Survey
* Your assessment is very important for improving the work of artificial intelligence, which forms the content of this project
Download (in English) file
Document related concepts
no text concepts found
Transcript
Faculty of Physics
Saint Petersburg State University
Saint Petersburg
2011
1
Edited by S.F. Bureiko and S.L. Berdnikov
ADDRESS:
Faculty of Physics
St. Petersburg State University,
Ulianovskaya ul. 1, Petrodvorets,
St. Petersburg, 198504,
Russia.
http://www.phys. spbu.ru
2
Saint Petersburg State University
St.
Petersburg
State
University
was
established
simultaneously with the Academy of Sciences and a Gymnasium
(Grammar School) by a decree of Peter the Great on 28 January
1724.
An outstanding place in the history of St. Petersburg
University belongs to Mikhail Lomonosov, a great scientist and
organizer of Russian education. His life and work were inseparably
connected with the Petersburg University for over 30 years.
Lomonosov came here from Moscow as one of a group of students
of the Slavic-Greek-Latin Academy and passed all the way to rise to
the post of professor and then University Rector. After his return to
St. Petersburg in 1741 after a trip abroad, Lomonosov began his
teaching career. The young scientist prepared courses of lectures for
university students, including a course of physics in Russian (1746).
In January 1760 the Academy President entrusted Lomonosov with
the sole management of the
3
University and Gymnasium, i.e. actually appointing him rector.
After Lomonosov’s death in 1765 the educational
departments of the Academy of Sciences – the University and the
Gymnasium, were subjected to transformations. The turning point in
the fate of the University came early in 1819, ending the nearcentury-long initial stage in its development. On February 8, 1819,
the University was re-established by a decree of Alexander I. There
were initially three faculties: History and Philology, Philosophy and
Law, and Physics and Mathematics each further divided into
sections; the University preserved this structure until 1918. In 1916
the teaching staff of the University comprised 379 persons, including
81 full professors, 200 assistant professors and 81 assistants; the
students numbered 5964, of these 2197 were at the Faculty of
Physics and Mathematics (1220 in the section of physics and 977 in
that of mathematics).
4
The year of 1917 opened a new phase in the history of St
Petersburg University, a time of violent shocks and turmoil and
ordeals, of great expectations and bitter disappointments.
Throughout this period the wonderful vitality of the University staff
manifested itself in intense creative work, in organization of new
research institutes, departments and laboratories and in
establishment of new areas and schools of research. The teachers
and researchers made every effort to keep up the University’s high
standards in training specialists and continued working hard,
selflessly, even enthusiastically, obtaining important scientific results.
The Great Patriotic War of 1941-1945 was to the University,
just as to the whole country, a time of severe trial of all physical,
intellectual and moral resources. More than 2500 undergraduate and
postgraduate students, lecturers, researchers, and technicians
fought at the front many of them giving their lives for their country. In
March 1942, Leningrad State University was evacuated to the city of
Saratov, where, under extremely hard conditions, teaching and
research were continued. In June 1944 the University returned to its
hometown; within a short time the university buildings damaged by
bombing and shelling were restored and studies were resumed on 2
October 1944.
The period after the end of the Second World War was a time
of intensive cooperation in research, merger of related disciplines,
introduction of mathematical methods both in sciences and the arts.
In the 1960s and 1970s the University researchers showed
outstanding achievements in physics, mathematics, chemistry,
biology, geology and geography. The opening of new Faculties,
Institutes, Departments and laboratories, rapid development of
research and the necessity to advance the teaching process made it
imperative to create a new University centre in Stary Petergof (Old
Peterhof) near Leningrad. In the 1960s, the Old Peterhof site
seemed the best solution, highly promising for further expansion of
the University. Reality proved to be more complicated, however.
5
In recent years, while overcoming numerous difficultie s,
the staff of St. Petersburg University has been using the new
possibilities to do everything in order to preserve and confirm
its leading position in the sphere of higher learning in Russia.
At present, over 32,400 students study in 323 areas of learning
at
the
24
faculties
of
St. Petersburg
University
Altogether, about 6,000 teachers are employed at the University
including 1,000 Doctors of Science and over 2,500 Candidates of
Sciences (PhD), 40 academicians of the State Academies of
Sciences. Owing to a special significance of the St. Petersburg
University as a Russian and international centre of education,
scientific research and culture, and in connection with the 275th
anniversary of its foundation, the Russian Government has issued a
decree “On St. Petersburg University” as of 1 November 1997. This
document is not merely an acknowledgment of the past and present
achievements of St. Petersburg University but an expression of
support to its desire to become a leading classical university in the
21st century.
Today, the staff of the University are working to fulfill this
strategic task.
In November 2009 President of the Russian Federation D.
Medvedev issued the edict which specified the University special
status of the unique educational and research complex, an oldest
higher education institution in the country which assumes paramount
importance for the development of the Russian society. By virtue of
law the University has acquired a right to design its own educational
programs and issue University degree certificates of its own format.
6
Faculty of Physics
The Faculty of Physics of the St. Petersburg State University
has the structure which provides students with a solid educational
basis and enables them to take part in fundamental high level
research in line with modern standards. Practically all modern trends
in physics, both experimental and theoretical, are presented in
different departments of the Faculty of Physics.
During the 1746-1747 academic year M.V.Lomonosov, a
graduate of the University, gave the first course of physics in
Russian. He used a textbook by C.Wolff, which he translated into
Russian. Valuable contribution to this science was made by
Professor E.C.Lentz, who held the Chair of Physics from 1835 to
1862. Lentz’s Law (heat generation by electric current) and the law
of electromagnetic induction are known to any schoolboy.
7
In the second half of XIX century one of the first physics
laboratories for students in Europe was opened in the University by
Professor F.F. Petrushevsky. In September 9, 1901 the first Russian
Institute of Physics was established at St.Petersburg University, that
was the first building especially constructed for physicists in Russia.
A whole generation of students studied physics using Professor O.
Khvolson’s textbook consisting of many volumes. Main enthusiast
and the second director of new institute was Professor of Physics I.I.
Borgman (March 1902-1914). He was also one of the first editors of
the physics part of the “Journal of Russian Physical and Chemical
Society” established at the St. Petersburg University in 1872. Since
1931 this journal is published in Moscow by the Russian Academy of
Sciences; it is known now to any physicist under the title The Journal
of Experimental and Theoretical Physics – JETP.
Since 1915 the Institute of Physics was directed by Professor
(later - Academician) D.S. Rozhdestvensky who was well known due
to his outstanding works in atomic spectroscopy, especially in
experiments on anomaly dispersion. He made a great contribution to
organize the high-class research work at the Faculty. The Faculty of
Physics was created in the Leningrad State University in 1933 after
the division of the Faculty of Physics and Mathematics. In 1971-1976
the Faculty of Physics was moved to new campus in Stary (Old)
Peterhof, which is situated in 35 km on the southwest from St.
Petersburg in a marvellous suburban area of the city, in
Petrodvorets. In 1999, when world physical community celebrated
centenary of the outstanding theoretician, Academician Vladimir
Aleksandrovich Fock (1898-1998), the Institute of Physics got its
present official name: V.A.Fock Institute of Physics.
8
Nowadays, the Faculty includes two research institutes in its
structure: the Institute of Physics and the Institute of Radiophysics.
The names of such famous scientists as the Nobel Prize Winners
N.N. Semenov (1956), L.D. Landau (1962), A.M. Prokhorov (1964),
Professors V.A. Fock, A.A. Friedmann, V.R. Bursian, P.I. Lukirsky,
V.M. Chulanovsky, D.V. Skobeltsin, Ya.I. Frenkel, E.F. Gross, S.E.
Frish, A.N. Terenin, G.A. (George) Gamov, V.N. Tsvetkov, V.A.
Ambartsumyan, K.Ya. Kondrat’ev, L.D. Faddeev, S.P. Merkur’ev et
al, are connected with the Faculty of Physics.
The Faculty of Physics is managed by the Dean and the
Scientific Board, both bodies elected for the five years term.
Scholarship is being advanced through the increasing
specialisation within discrete subjects, in the borderlands between
subjects and in the interplay between different subject areas. At
graduate level the Physics Faculty offers the following degrees:
Bachelor Degree (4 years of study), Master Degree (2 years of
study). The Faculty offers also 3-year postgraduate programs
leading to Candidate (Ph.D.) degree in Physics and Mathematics.
Such a program can be undertaken in any research group. The
Faculty offers three courses for undergraduate students: Physic,
Radiophysics and Applied Physics and Mathematics, and two
courses in the mastership: Physica and Applied Physics and
Mathematics.
We will be looking at mature individuals who have been able
to optimally develop their unique talents during a flexible educational
experience – at individuals who have learned how to learn, and who
can apply their special aptitudes to the greater good. Our Faculty
exists for students who seek for that kind of education.
9
Nowadays, the Faculty of Physics includes 19 Research and
Educational Departments:
Atmospheric Physics
Computational Physics
General Physics I (Quantum Electronics)
General Physics II (Chemical Physics)
Molecular Biophysics
Molecular Spectroscopy
Nuclear Physics
Optics
Photonics
Physics of High Energies and Elementary Particles.
Polymer Physics
Pure Mathematics and Mathematical Physics
Quantum Magnetism
Quantum Mechanics
Radiophysics
Solid State Electronics
Solid State Physics
Statistical Physics
Terrestrial Physics
The research unit of the Faculty is comprised of two Research
Institutes, which are the V.A. Fock Research Institute of Physics and
the Research Institute of Radiophysics. Research divisions of all the
Departments except of the Departmnet of Radiophysics belong to
the Fock Institute of Physics. To further develop research activities in
radiophysics, and, in partilular, to extend Academician Fock’s
activities in the theory of diffraction and wave propagation around the
Earth, in the year of 1995 the Institue of Radiophysics was
established as the research unit of the Department of Radiophysics.
10
The main fields of the Faculty’s research activities include:
(a) Theoretical study of physical properties of elementary particles,
atoms, molecules, liquids, and solids. Development of new methods
and theories in physics of atomic, molecular and condensed
systems. Physics in spaces with extra dimensions and noncommutative coordinates.
(b) Complex study of electronic and molecular phenomena in solids
and on inter-phase boundaries;
(c) Linear and nonlinear physical optics, holography and physics of
lasers. Quantum optics and its applications in quantim informatics.
Low-dimentional semiconductor lasers. Study of physical properties
of substance and interaction processes in gases, liquids and plasma
(including active media of optical quantum generators and planet's
atmosphere);
(d) Study of atomic nucleus structure and the mechanism of nuclear
interactions;
(e) Experimental and theoretical studies of optical, electronic,and
magnetic properties of nanostructures and non-linear processes in
nano-objects.The development of neutron, X-ray, optical
spectroscopy methods for the investigation of nanocomposites.
(f) Study of molecular structure and physical properties of polymers
and disperse systems. Investigation of liquid crystals, phase
transitions and intermolecular interactions in condensed media;
(g) Study, modelling and monitoring of physical fields and processes
in
geospheres
(atmosphere,
ionosphere,
magnetosphere,
hydrosphere, earth-crust, mantle, core)
(h) Theoretical and experimental investigations into electromagnetic
radiation and wave propagation in different media, non-linear waves
and processes. Fundamental problems of radiophysics in satellite
navigation. Radiophysical methods for exploring near-the-Earth
space.
They are described in the following sections for each of the
Faculty’s Department in more detail.
11
Research in the natural sciences is, by
tradition, very international. This is also the
case with our Faculty of Physics. To conduct their accelerator
experiments, our physicists travel to CERN (Switzerland) and to
DESY (Germany). The Institute has long-time and productive
collaboration with the Universities and Research Institutes in
Germany and USA, Sweden and Finland, Spain and The
Netherlands, Switzerland and Italy, Great Britain and France, Poland
and Czech Republic, Canada and Japan, Republic of Korea and
China, and so on, and so on. And – naturally – visiting researchers
and graduate students come to Old Peterhof from all corners of the
earth, attracted by the experts and the facilities that have achieved
international prominence.
In centrum: Nobel
Prize Winner
Professor Ilya
Prigogine (Belgium),
the Doctor of Honour
of St. Petersburg
State University,
among the physicists
during his visit to St.
Petersburg
12
Academician Vladimir Aleksandrovich Fock
( 1898 - 1974 )
V.A. Fock and Louis de Broglie
in Paris, 1967
Vladimir Aleksandrovich Fock, one the greatest theoretical
physicist of the XX-th century, was born in St. Petersburg. During all
his life V.A.Fock was strongly connected with St. Petersburg where
he was teaching at the University nearly 50 years. In 1916 V.A.Fock
finished the real school and entered the faculty of physics and
mathematics of the Petrograd University, but soon joined up the
army as volunteer. In 1918 after demobilization he resumed his
studies at the University.
In 1922 he graduated from the University and was kept at the
University to prepare for professorship. Before graduation from the
University, V.A.Fock had already been the author of two scientific
publications - one on the old quantum mechanics and the other on
mathematical physics.
13
Since then his scientific and teaching activity was mostly
connected with the University (holding a post of graduated student,
assistant, associate professor, professor, head of the chair and head
of the theoretical physics department of the Physical Institute).
Taking into account the outstanding scientific achievements
of V.A.Fock the Academy of Sciences of the USSR elected him as a
correspondent member in 1932 and as an academician in 1939. He
was awarded the highest scientific domestic prizes.
The works of V.A.Fock, devoted to a wide area of problems
of theoretical physics: among which are quantum mechanics,
quantum field theory, general relativity and mathematical physics
(especially the diffraction theory) etc., had deeply influenced the
modern development of theoretical and mathematical physics and
received the world-wide recognition. Sometimes his views differed
from the conventional ones. Thus, he argued with deep physical
reasoning about using the term «theory of gravitation» instead of
«general relativity». Many results and methods he developed
reflected in such notions as Fock space, the Fock method in the
second quantization theories, the Fock proper time method, the
Hartree-Fock method, the Fock symmetry of the hydrogen atom and
others. In his works on theoretical physics not only did he skillfully
apply the advanced analytical and algebraic methods, but also
created systematically new mathematical tools when the existing
approaches were insufficient. His studies emphasized the principal
significance of modern mathematical methods for theoretical
physics, a fact that has become important nowdays.
With time the significance of works of classics of science
becomes more and more obvious, and V.A. Fock is undoubtedly
such a classic. His name will stay forever in the history of science.
14
Faculty of Physics in Numbers
Staff (January, 2011)
Students (September 2011)
1059
253
Post-graduate students
(January 2011)
182
54
D. Sc. students (January
2011)
18
107
Dr.Sc. Theses (in 2010)
3
197
Ph.D. Theses (in 2010)
23
Total
a) D.Sc:
b) Ph.D
(c) Researchers
(d) Technicians
56
Publications (in 2010)
Papers
456
Books/monographs
11
Patents (in 2010)
Organization of conferences (2010)
4
21
15
Structure of the Faculty's Research Financing Funds in 2010
16
PHYSICS OF ATMOSPHERE
Professor Yurii M. Timofeyev, Head of the Department
M.Sc. 1963, Ph.D. 1968, D.Sc. 1985
Research staff:
Prof., Dr. Gustav M. Shved, Prof.,Dr. Lev S.
Ivlev, Prof., Dr. Nikolay M. Gavrilov, Prof., Dr Eugene F. Mikhailov,
Dr. Genrik A. Nikolsky, Dr. Anatoly V. Poberovski, Dr. Alexandr V.
Polyakov, Dr. Vladimir S. Kostsov, Dr. Rada O. Manuilova,
Dr. Dmitry V. Ionov, Dr. Vladimir P. Ogibalov, Dr. Valentin A.
Yankovsky, Dr. Sergey S. Vlasenko, Dr. Tatiana I. Ryshkevich, Dr.
Aleksei O. Semenov, Dr. Yana A. Virolainen, Dr. Alexandr V.
Vasiliev, Dr. Vladimir Kudriashov, Dr. Maria Makarova, Dr. Anton V.
Rakitin, S.G. Semakin.
17
Education
Postgraduate (bachelor of science)
Theoretical atmospheric optics
Remote sensing of the planet atmospheres
Atmospheric dynamics
Atmospheric photochemistry
Physics of clouds and atmospheric aerosols
Magistracy
Monitoring and modeling of the planet atmospheres
Physics of the atmosphere and the ocean
The main courses
Theory of radiative transfer in the atmosphere.
Circulation and energetics of the atmosphere
Experimental methods of atmospheric dynamics
Molecular spectroscopy of atmospheric gases
Mathematical basis of remote sensing of the atmosphere
Fundamentals of solar-terrestrial physics
Introduction to the theory of climate
Experimental optics of the atmosphere
Physics of remote sensing methods
Applications of Fourier Spectroscopy in Atmospheric
Research
Elective courses
Wave processes in the atmosphere
Atmospheric photochemistry
Experimental investigations of atmospheric aerosols physics
Kinetics of atmospheric chemical reactions
Numerical methods of atmospheric dynamics
Thermodynamics of atmospheric aerosols
Numerical methods in the theory of non-equilibrium radiation
transfer
18
Computer simulation in optics of non-spherical aerosols
Molecular collisions and spectra of atmospheric gases
Experimental methods of ecological monitoring
Basic physics of ecology
Ground-based Remote Sensing of Trace Gases
Research topics
Problems of radiative transfer in the atmosphere.
Investigations of atmospheric absorption characteristics.
General circulation and wave processes in the middle and
upper atmosphere.
Direct and inverse problems of atmospheric optics.
Field and laboratory investigations of spatial-temporal
structure of concentration, dispersivity, chemical and
component content, and morphology of atmospheric
aerosols.
Development of remote sensing methods for studying the
planet atmospheres.
Software for remote sensing of the atmospheric and surface
parameters
Interpretation and validation of satellite measurements.
Remote (satellite, ground-based) measurements of the
column amount of different trace gases.
Radiative transfer in the rotational-vibrational bands of
molecules under local thermodynamic equilibrium breakdown
in planetary atmospheres.
Kinetics of molecules in excited vibrational and electronic
states.
Simulation of optical characteristics and estimation of the size
distribution function of atmospheric aerosols of natural and
anthropogenic origin.
Laboratory and field studies of the processes of producing
and evolving the aerosols (condensation, coagulation,
diffusion, sedimentation, heterogeneous chemical reactions,
charging, elutriation, etc.) including the fractal-similar
particles.
19
Monitoring of ecological state of the environment.
Experimental investigation of radiative сonnection of the
system "Sun - Earth’s atmosphere”.
3-D numerical modeling of regional fields of trace gases
Special equipment
The complex of experimental equipment for studying the
physical characteristics of condensation aerosols with solid
disperse phase.
Sun IR spectrometer for ground-based measurements of
solar spectra in the 3 5 m range with spectral resolution of
~ 0.3 cm-1.
Aureole photometer for measuring the aerosol scattering in
the atmosphere (the spectral range is 0,4 0,9 m).
spectrometer DH-10 UV, two pointing broadband
photometers, two-channel spectral photometer, infra-red
optical hygrometer, reference Angstrem pyrgeliometer №
575, оzоnometer, microbarograph
DOAS system for O3 and NO2 twilight sounding.
MW ozonometer
Monographs
1. Ivlev, L.S., Yu.A. Dovgalyuk. Physics of atmospheric aerosol
systems. SPb, SPbSU Publ., (1999) 258pp.
2. Yu.M.Timofeev., A.V.Polyakov // Mathematical aspects of
atmospheric remote sensing. SPbSU Publ., SPb, (2001) 188 pp
(in Russian)
3. Yu. M. Timofeev, A.V. Vasil'ev. "Theoretical basis of
atmospheric optic. SPb., Science (2003) 474pp.
4. Vasilyev A.V., Melnikova I.N. Short-wave solar radiation in the
Earth atmosphere. Calculation. Observation. Interpretation. SPb, SPbSU Publ. (2002) 388pp.
5. Yu.M. Timofeyev, A.V. Vasil'ev. Theoretical Fundamentals of
Atmospheric optics. CIPS Cambridge International Science
Publishing, 2008, pp. 480
6. Yu.M. Timofeyev, Global system for monitoring parameters of
atmospheric and surface parameters. SPbU, 2010, 129 pp.
20
Selected papers
1. Poschl U., S. T. Martin, B. Sinha, Q. Chen, S. S. Gunthe, J. A.
Huffman, S. Borrmann, D. K. Farmer, R. M. Garland, G. Helas,1 .
L. Jimenez, S. M. King, A. Manzi, E. Mikhailov, T. Pauliquevis, M.
D. Petters, A. J. Prenni, P. Roldin, D. Rose, J. Schneider, H. Su,
S. R. Zorn, P. Artaxo, M. O. Andreae.: Rainforest Aerosols as
Biogenic Nuclei of Clouds and Precipitation in the Amazon.
Science, 329,1513-1515, DOI: 10.1126/science.1191056329,
supporting
.material
pp.1-20,
www.sciencemag.org/cgi/content/full/329/5998/1513/DC1, 2010.
2. Poberovskii A.V.. High-resolution ground measurements of the
IR spectra of solar radiation. Atmospheric and Oceanic Optics,
23, 2, 161–163, 2010:.
3. de Laat A.T.J., A.M.S. Gloudemans, H. Schrijver, I. Aben,
Y. Nagahama, K. Suzuki, E. Mahieu, N.B. Jones, C. Paton-Walsh,
N.M. Deutscher, D.W.T. Griffith, M. De Maziere, R. Mittelmeier,
H. Fast, J. Notholt, M. Palm, T. Hawat, T. Blumenstock,
C. Rinsland,
A.V. Dzhola,
E.I. Grechko,
A.M. Poberovskii,
M.V. Makarova, J. Mellqvist, A. Strandberg, R. Sussmann,
T. Borsdorff, and M. Rettinger,2010: Validation of five years
(2003–2007) of SCIAMACHY CO total column measurements
using ground-based spectrometer observations.Atmos. Meas.
Tech.
Discuss.,
3,
2891–2930, www.atmos-meas-techdiscuss.net/3/2891/2010/ doi:10.5194/amtd-3-2891-2010.
4. Virolainen Ya.A., Yu.M. Timofeev, A.V. Polyakov, A.B.
Uspenskii,: Optimal parameterization of the spectra of outgoing
thermal radiation with the data of the IKFS-2 spaceborne IR
sensing device taken as an example. Atmospheric and Oceanic
Optics, 23, 3, 215–221,2010.
5. Semakin S.G., Timofeev Yu.M., Polyakov A.V., Virolainen Ya.A.
On determination of stratospheric aerosol microstructure from
limb scatter measurememnts. Atmospheric and Oceanic Optics,
23, 4, 334–338, 2010.
6. Ionov D.V., Tropospheric NO2 trend over St. Petersburg
(Russia) as measured from space. Russian Journal of Earth
Sciences, 11, ES4004, 2010. doi:10.2205/2010ES000437.
21
7.
Poberovskii
A.V.,
Polyakov
A.V.,
Yu.M.
Timofeev.
Measurements of the Hydrogen Fluoride Total Column Amount in
the Atmosphere over the Vicinity of St. Petersburg. Izvestiya,
Atmospheric and Oceanic Physics, 46, 2, 261–263, 2010.
8. Poberovskii A.V. , M.V. Makarova, A.V. Rakitin, D.V. Ionov, and
Yu.M. Timofeev. Variability of the Total Column Amounts of
Climate Influencing Gases Obtained from Ground-Based High
Resolution Spectroscope. Doklady Earth Sciences, 432, 02, 656–
658, 2010.
9. Ionov D.V., Timofeev Yu.M. Regional Space Monitoring of
Nitrogen Dioxidein the Troposphere. Izvestiya, Atmospheric and
Oceanic
Physics, 45,
4,
434-443,
DOI:
10.1134/S0001433809040045, 2009.
10. Feofilov, A. G., Kutepov, A. A., Pesnell, W. D., Goldberg, R. A.,
Marshall, B. T., Gordley, L. L., Garcнa-Comas, M., LуpezPuertas, M., Manuilova, R. O., Yankovsky, V. A., Petelina, S. V.
and Russel J.M. Daytime SABER/TIMED observations of water
vapor in the mesosphere: retrieval approach and first results.
Atmos. Chem. Phys., 9, 8139–8158, 2009.
11. Shved G.M., Karpova N.V., Ammosov P.P., Gavrilyeva G.A.,
Perminov V.I., Semenov A.I. Detection of short-period global
waves from nightglow observations. Geomagnetism and
Aeronomy, V. 49, No 3, P. 400-402. 2009.
12. Ionov, D.V., Y. M. Timofeyev, V. P. Sinyakov, V. K. Semenov, F.
Goutail, J.-P. Pommereau, E. J. Bucsela, E.A.Celarier, and M.
Kroon, Ground-based validation of EOS-Aura OMI NO2 vertical
column data in the midlatitude mountain ranges of Tien Shan
(Kyrgyzstan) and Alps (France). J. Geophys. Res., 113, D15S08,
doi:10.1029/2007JD008659, 2008.
13. Rose D., Gunthe S.S., Mikhailov E.F., Frank G.P., Dusek U.,
Andrea M.O., and Poeschl U. Calibration and measurement
uncertainties of a continuous-flow cloud condensation nuclei
counter (DMTCCNC): CCN activation of ammonium sulfate and
sodium chloride aerosol particles in theory and experiment.
Atmos. Chem. Phys. 8, 3, 1153-1179, 2008
22
14. Celarier E.A., Brinksma E., Gleason J.F., Veefkind J.P., Cede A.,
Herman J.R., Ionov D., Goutail F., Pommereau J., Lambert J.,
Van Roozendael M., Pinardi G., Wittrock F., Schonhardt A.,
Richter A., Ibrahim O.W., Wagner T., Bojkov B.R., Mount G.H.,
Spinei E., Chen C., Pongetti T., Sander S.P., Bucsela E., Wenig
M., Swart D., Volten H., Kroon M., and Levelt P. Validation of
Ozone Monitoring Instrument Nitrogen Dioxide Columns. J.
Geophys. Res. doi:10.1029/2007JD008908 , 2008.
15. Semenov A.O., Shved G.M. Upper thermal boundary layer of
planetary atmosphere: An attempt of developing a general model.
Icarus, 194, 1, 290-302. 2008.
16. Semenov A.O., Shved G.M. Parameterization of the coefficient of
molecular
thermal
conductivity
of
the
thermosphere.
Geomagnetism and Aeronomy, 48, 6, 823-828, 2008.
17. Polyakov A.V., Timofeev Yu.M., Virilainen Ya.A. Polar
Stratospheric
Clouds
from
Satellite
Observational
Data. . Izvestiya, Atmospheric and Oceanic Physics, 44, 4, 448–
458, 2008.
18. K. Hocke, N. Kampfer, D. Ruffieux, L. Froidevaux, A. Parrish, I.
Boyd, T. von Clarmann, T. Steck, Y. M. Timofeev, A. V. Polyakov,
and E. Kyrцlд. Comparison and synergy of stratospheric ozone
measurements by satellite limb sounders and the ground-based
microwave radiometer SOMORA // Atmos. Chem. Phys., 7, 41174131, 2007.
19. Wetzel G., Bracher A., Funke B., Goutail F., Hendrick F.,
Lambert J.-C., Mikuteit S., Piccolo, M. Pirre, A. Bazureau, C.
Belotti, T. Blumenstock, M. De Mazi`ere, H. Fischer, N. Huret C.,
Ionov D., Lґopez-Puertas M., Maucher G., Oelhaf H., Pommereau
J.-P., Ruhnke R., Sinnhuber M., Stiller G., Van Roozendael M.,
and Zhang G. Validation of MIPAS-ENVISAT NO2 operational
data // Atmos. Chem. Phys., 7, 3261-3284, 2007.
20. Timofeyev Yu.M., Polyakov A.V., Kyrola E.Comparison and
synergy of stratospheric ozone measurements by satellite limb
sounders and the ground-based microwave radiometer
SOMORA. Atmos. Chem. Phys., 7, 4117-4131, 2007.
21. Mikhailov E.F., Vlasenko S.S.,. Podgorny I.A. , Ramanathan V.
and Corrigan C.E. Optical properties of sootwater drop
agglomerates: An experimental study. J.Geoph.Res. V. 111,
D07209, doi:10.1029/2005JD006389, 2006.
23
22. Yankovsky V.A., Manuilova R.O. Model of daytime emissions of
electronically-vibrationally excited products of O3 and O2
photolysis: Application to ozone retrieval. Ann. Geophys., 24, 11,
2823-2839, 2006.
23. Gavrilov N.M., Fukao S., Hashiguchi H., Kita K., Sato K.,
TomikawaY., Fujiwara M.Combined MV radar and ozonesonde
measurements of turbulence and ozone fluxes in the tropostratosphere over Shigaraki, Japan. Geophys. Res. Lett., 33, 9.
L09803,10.1029/2005GL024002. 2006.
24. Jacobi Ch., N.M. Gavrilov, D. Kurschner. Gravity wave
climatology and trends in the mesosphere/lower thermosphere
region deduced from low-frequency drift measurements 19842003. J.Atmos. Solar-Terr. Phys., 68, 17, 1913-1923, 2006.
25. Ogibalov V.P., Khvorostovskii S.N., Shved G.M. Incsease in the
carbon dioxide infrared emissions during solar photon events.
Geomagnetism and Aeronomy, V. 46, No 2, P. 159-167. 2006.
26. Ionov D.V., Sinyakov V.P., Semenov V.K. Validation of GOME
(ERS-2) NO2 vertical column data with ground-based
measurements at Issyk-Kul (Kyrgyzstan). Adv. Space Res., 37,
2254-2260, 2006.
Selected Projects
1. Temperature dependence of the concentration of active
nucleation centers on the surface of model particles and
atmospheric aerosols. Dr. T.I. Ryshkevich, Grant of the
Russian Foundation for Basic Research (RFBR) 10-03-00950-а,
2010-2012.
2. Numerical three-dimension modeling propagation of
mesoscale nonlinear breaking waves in the middle and
upper atmosphere using super-computer technologies.
Prof., Dr. N.M. Gavrilov, Grant RFBR 10-05-00719-а, 2010-2012.
3. The development and realization of a new synergetic
method for monitoring of trace atmospheric gases. Prof., Dr.
Yu.M. Timofeyev, Grant Min. Educ. and Science, contract №
16.740.11.0048. 2010-2012.
24
4. Monitoring and modeling of anthropogenic impact on
atmospheric gaseous composition over North-west Russia.
Dr. M.V. Makarova, Grant Min. Educ. and Science, 2010-2012
5. Satellite monitoring of atmospheric and surface parameters
by Fourier spectrometer IRFS-2 (satellite “Meteor”). Prof.,
Dr. Yu.M. Timofeyev, Grant RFBR 09-05-00797-а, 2009-2011.
6. Amorphous and crystalline aerosol particles: effect on
phase transitions and hygroscopic growth. Prof., Dr. E.F.
Mikhailovi, Grant RFBR 09-05-00883-а, 2009-2011.
7. Ozone and atomic oxygen retrieval from the measured
intensities of molecular oxygen emissions in the Middle
Atmosphere Dr. V.A.Yankovsky, Grant RFBR 09-05-00694,
2009-2011.
8. Transfer of radiation in the near-infrared ro-vibrational
bands of CO2 in the case of local thermodynamic
equilibrium breakdown taking account for aerosol scattering
in the Martian atmosphere: a development of new method
for
remote
sounding
of
the
Martian
aerosols.
Dr. V.P. Ogibalov, Grant RFBR 08-05-00862, 2008-2010.
9. Investigation of troposphere and stratosphere dynamics on
the base of geostationary satellite measurements. Prof.,
Dr. A.V. Polyakov , Grant No. 08-05-00885 – а, 2008-2010.
10. Experimental investigation of greenhouse and ozone
depleting trace gases by Fourier spectrometer.
Dr A.V.Poberovski, Grant RFBR 08-05-00857–а, 2008-2010.
11. Vertical structure of ozone from IR and MW ground-based
measurements. Dr. Virolainen Ya.A. Grant RFBR 08-0500952-а, 2008-2010.
12. Experimental and modeling of CO transformation content
in the atmosphere. Dr. Makarova M.V., Grant RFBR 0500708-а, 2007-2009.
13. Study of short-period global atmospheric waves by
synchronous measurements of nightglow, ground
pressure, and seismic oscillationsStudy of short-period
global atmospheric waves by synchronous measurements
of nightglow, ground pressure, and seismic oscillations.
Prof.,Dr. G.M. Shved, Grant RFBR 07-05-00475, 2007-2009.
25
14.
15.
16.
17.
18.
26
Numerical three-dimension modeling of the impact of
mesoscale waves on the general circulation and admixture
transport in the middle atmosphere. Prof., Dr. N.M. Gavrilov,
Grant RFBR 07-05-00913-а, 2007-2009.
Long term trend of ozone content from satellite
measurements. Grant No. Prof., Dr. Timofeyev Yu.M., Grant
RFBR 06-05-64909-а, 2006-2008.
Investigation of temperature and trace gas from satellite
for nonstationary and inhomogeneous stratomesosphere.
Dr. V.S. Kostsov, Grant RFBR 06-05-64987-а, 2006-2008.
Microphysical properties of stratospheric aerosol and PSC
from satellite measurements. Prof., Dr. A.V. Polyakov, Grant
RFBR 05-05-65305-а, 2005-2007.
Non-stationary model of kinetics of the electronvibrationally excited products of photodissociation of
ozone and oxygen in the Middle Atmosphere
Dr. V.A.Yankovsky, Grant RFBR 05-05-65318, 2005-2007.
Computational Physics
Professor Sergey L. Yakovlev,
Head of the Department (Chair of the Department)
M. Sc. 1980, Ph. D. 1983, D. Sc. 1998
Full Professors: Ivan V. Andronov, Viktor B. Kurasov Serguei Yu.
Slavyanov, , Yurii F. Ryabov, Andrey V. Tsiganov;
Associate Professors: Vasilii A. Buslov, Vadim V. Monakhov, Sergei
A. Nemnyugin, Anatolii P. Scherbakov, Margarita M. Stepanova,
Aleksey B. Utkin, Evgenii A. Yarevsky;
27
Master Program in Physics
Title: Computational physics and computer-based systems of
scientific researches 010700/22-14
Master Program in Applied Physics and Mathematics
Title: Computational Physics 010600/52-05
Major courses
Object-oriented programming
Internet programming languages
Methods of Computational Physics
Computational methods in Physics
Specialization practicum
Databases in systems of scientific researches
Data bases
Introduction in wavelet analysis
Discrete mathematics, graphs theory. Algorithms
Differential and difference equations
Quantum scattering theory for few body systems
Quantum integrable systems
Pade approximations
Network technologies
Symbolic calculations
System analysis and data processing
Scattering theory
Discrete mathematics, graphs theory, algorithms, encoding,
automats
Mathematical methods of modeling of charged particles beams
Java programming language
Mathematical methods of optics of the charged particles
Parallel programming
Structures of the data and methods of work with them
Chaos and stochastics
28
Research Topics
Mathematical and computational methods for solving few
body problems in atomic, molecular and nuclear physics
Differential and finite-difference equation
Finite dimensional integrable systems in classical and
quantum mechanics
High performance and distributed calculations and systems.
GRID
Object oriented programming and applications
Selected recent publications
1. C.-Y. Hu, S.L. Yakovlev, Z.Papp, Positron annihilation above the
Positronium formation threshold in e^+ - H scattering. Nuclear
Instruments and Methods in Physics Research B 247 (2006) 2530
2. S.L. Yakovlev, C-Y Hu and D. Caballero, Multichannel formalism
for positron-hydrogen scattering and annihilation, J. Phys. B: At.
Mol. Opt. Phys. 40 (2007) 1675-1693.
3. S.L. Yakovlev, C.Y. Hu, Multichannel scattering and annihilation
in positron hydrogen system. Few Body Systems, 44 (2008)
237-329.
4. M.V. Volkov, N. Elander, E. Yarevsky, S.L. Yakovlev, Solving
the Coulomb scattering problem using the complex scaling
method. Euro Phys Letters 85 (2009) 30001
5. N. Elander, M.V. Volkov, A. Larson, M. Stenrup, J.Z. Mezei,
E.Yarevsky, S.Yakovlev
Quantum Scattering with Driven Schrödinger Approach and
Complex Scaling.
Few Body Systems 45 (2009) 197-201
29
6. S.L. Yakovlev, M.V. Volkov, E. Yarevsky and N. Elander
The Impact of Sharp Screening on the Coulomb Scattering
Problem in Three Dimensions
J. Phys. A: Math. Theor. 43 (2010) 245302.
7. M. V. Volkov, S. L. Yakovlev, E. A. Yarevsky, and N. Elander
Potential splitting approach to multichannel Coulomb scattering:
The driven Schrödinger equation formulation, Phys. Rev. A 83,
032722 (2011)
8. Yu. A. Grigoryev, V. A. Khudobakhshov and A. V. Tsiganov
On Euler superintegrable systems J. Phys. A: Math. Theor. 42
075202 (2010)
9. A. V. Vershilov and A. V. Tsiganov
On bi-Hamiltonian geometry of some integrable systems on the
sphere with cubic integral of motion
J. Phys. A: Math. Theor. 42 105203 (2010)
30
General physics I (Quantum Electronics)
Professor I.Ch. Mashek, Head of the Department
M.Sc. 1978, PhD 1983, D.Sc. 2000
Units:
Laboratory of Coherent Optics
Laboratory of Quantum Optics
Laboratory of Laser Physics
Laboratory of Nonlinear Fiber optics
31
Laboratory of Coherent Optics
Academic and Research staff:
Head of the laboratory Dr.Sc. R.I. Semenov,
Prof. E.I. Butikov Prof. N.N. Rozanov, Sen. Res. Yu.I.
Anisimov, Leading Res. V. A. Polishuk Sen. Res., Associate Prof
G.P. Anisimovа, Associate Prof. T.L. Tkachenko Associate Prof
V.G. Mishakov, Associate Prof A.S. Chirtsov Sen. Res. I.R. Krylov
Associate Prof A.I. Eihvald Sen. Res. M.V.Balabas, , , Sen. Res.
E.S. Dzlieva, , , engineer M.A. Ermolenko, Sen. Res. S.V. Gordeev,
Assistant Prof. A.Yu. Ivanov, Associate Prof A.I. Kanzerov, Sen.
Res., Associate Prof V.Yu.Karasev, Engineer N. B. Kosyh, ,
Engineer Yu. I. Limbah, , , Leading Res., Engineer E. A. Rybchikov,
Engineer K.V. Simon, Lecturer G.A. Tsygankova, Technician C.X.
Vasilieva.
Master Degree Program “Coherent optics”.
PhD program: Optics, Laser physics, Plasma Physics
The laboratory of coherent optics actively works with students
and PhD students offering modern courses and practical study in the
fields of plasma science, laser spectroscopy and electromagnetic
field with atomic structures interaction. The fundamental education is
supplemented with modern experimental tools, computer-based
specialized trainings covering wide range of optical atomic molecular
and plasma tasks. The laboratory actively cooperates with
international institutions in Europe and United States. The laboratory
consists of several scientific research groups.
Research topics:
laser spectroscopy
semi-empirical computer-based calculations of atomic structures in
electromagnetic fields.
laser control of super- and giper-sonic gas flows
plasma aerodynamics
plasma crystals: formation and control
microspine of dusty particle and discharge diagnosis
thin films for magnetometers
Optics of dispersed phase
32
Laser Physics Laboratory
Academic and Research staff: Prof. S.A. Pulkin, Head of Laser
Physics Lab; M. Balabas, Senior Res. Scientist; V.F. Boitsov,
Associate Prof.; E.A. Efremova, Lecturer; V.S. Ivanov, Assistant
Prof.; V.I. Korotkov, Senior Res. Scientist; V.V. Kozlov, Associate
Prof.; E.B. Pelyuhova, Associate Prof.; T.V. Radina, Leading Res.
Scientist; V.A. Sokolov; S.V. Uvarova, engineer; V.Yu. Venediktov,
Associate Professor.
Master Degree Program “Quantum Optics and Laser Physics”.
Key points of the Master Program
- training opportunities at universities and research centers in Russia
and Western Europe
- the cutting-edge research in the field of modern quantum and
nonlinear optics, and laser physics
- acquisition of real skills in research and computer modeling
- individual approach to the selection of training courses
- intensive study combined with practical research under supervision
of leading specialists
- individual research practices in leading research teams
- active use of computer, multimedia and information technologies in
educational process
PhD program: Laser Physics, Optics
Research topics
Nonlinear Optics
Nonlinear Photonics
Quantum Optics
Silicon Photonics
Classical and Quantum Solitons
Nanometrology
Quantum communications
Laser Physics
33
Laboratory of Quantum Statistical Optics
Academic and Research staff: Prof. Yu.M.Golubev; Prof.
I.V.Sokolov; Senior Teacher T.Yu.Golubeva; Postdoctoral fellow
V.A.Averchenko;
http://quantopt.phys.spbu.ru
Master Degree Program “Quantum Optics and Informatics
PhD program: Laser Physics, Optics
The Laboratory of Quantum Statistical Optics has recognized
expertise in theory and physics of various phenomena related to
statistics of light-matter interaction. Our laboratory investigated
spectroscopy of intensity fluctuations in atomic non-linear optics. An
important contribution to better understanding of the laser radiation
statistics was made by our group, when we suggested the subPoissonian laser with regular excitation of working medium. The first
demonstrations in mid 80'th of non-classical states of bright coherent
light (sub-Poissonian, squeezed etc.) with suppressed quantum
fluctuations stimulated our active theoretical research in this
direction, including the concept of photon-noise-free light wave
fronts and
quantum imaging. The idea to introduce optical
parallelism, coming from quantum imaging, to the schemes of
quantum information, such as quantum teleportation, super dense
coding, quantum memory etc., is stimulating our current research.
We deliver to our students and graduate students courses in such
areas as quantum theory of laser fluctuations and non-classical light,
optical methods of quantum information, cold atoms and others. The
students are actively involved into research, the graduate students
participate in international collaboration with leading groups in the
field and have a possibility to visit international scientific meetings
and schools.
Research topics
Theory of quantum fluctuations in lasers and sources of nonclassical light
Methods and approaches of theoretical quantum optics in
quantum information
Theory of parallel quantum memory for light (Quantum
holograms)
34
Laboratory of nonlinear fiber optics
Academic and Research staff:
Head of the laboratory Dr. A.V.Kurochkin,
Academic and Research staff:
Dr. A.A. Manshina, Dr. A.V. Povolotskiy, A.A. Shimko, A.V.
Gerasimov, I.E. Kolesnikov
The main direction of the research is laser-matter interaction with
novel optical materials (optical fibers, photonic crystals,
superlattices, metamaterials). Laboratory is also focusing in
development and realisation of methods of nanoscale materials and
structures creation.
Research topics
UV laser deposition;
Localized Laser-induced metal deposition;
Laser writing;
Nonlinear phenomena in fibers and photonic crystal fibers;
Laser-induced phenomena in amorphous and crystalline
materials
Cooperation list
-
Institute of chemistry of high pure substances, Russia Center of
fiber optics, Russia
Institute of optics, information and photonics, University of
Erlangen-Nuremberg, Germany
National Taiwan University of Science and Technology, Taiwan
Korea Institute of Machinery and Materials, Korea
Department of physics and related technologies, University of
Palermo, Italy
35
Selected papers 2007-2011
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
36
High quality anti-relaxation coating material for alkali atom
vapor cells” Balabas M.V., K. Jensen, W. Wasilevski, H.
Krauter, L. S. Madsen, J. H. Muller, T. Fenholz and E. S.
Polzik Optics Express, Vol.18, No. 6, 5825 (2010)
“Polarized alkali-metal vapor with minute-long transverse spinrelaxation time” Balabas M.V., T. Karaulanov, M. P. Letbetter
and D. Budker Phys. Rev. Letters 105, 070801 (2010)
“Quantum
noise
limited
and
entanglement-assisted
magnetometry” Balabas M.V., W. Wasilevski, K. Jensen, H.
Krauter, J. J. Renema and E. S. Polzik Pys. Rev. Letters 104,
133601 (2010)
Butikov E.I. Comment on "Energy in one-dimensional linear
waves in a string" // Europ. J. Phys. 2010. V.31. N.6. P.71-79.
Polischuk V. et. All. Self-alignment and conductivity of a glow
discharge // J. Phys. B. 2009, 42
Balabas M.V. et. all. Electric-field-induced charge of alcali
vapor density in paraffin-cjated cells. // Phys. Rev. A., v. 79
V. Yu. Karasev, E. S. Dzlieva, A. Yu. Ivanov, A. I. Éikhval’d,
M.S. Golubev, M.A. Ermolenko Single dust-particle rotation in
glow-discharge plasma // Phys. Rev. E 79, 026406 (2009).
Rosanov N. N., Kozlov V.V., and Wabnitz S. (2010): MaxwellDrude-Bloch dissipative few-cycle optical solitons, Phys. Rev.
A 81, 043815.
Kozlov V.V. and Wabnitz S. (2010): Quasi-parabolic pulses in
a coherent nonlinear optical amplifier, Opt. Lett. 35 (12), 20582060.
Wabnitz S. and Kozlov V.V. (2010): Harmonic and
supercontinuum generation in quadratic and cubic nonlinear
optical media, J. Opt. Soc. Am. B 27 (9), 1707-1711.
Kozlov V. V. and Wabnitz S. (2011): Instability of optical
solitons in the boundary value problem for a medium of finite
extension, Lett. Math. Phys., 96, 405-413.
Kozlov V.V. and Wabnitz S. (2010): Theoretical study of
polarization attraction in high birefringence and spun fibers,
Opt. Lett. 35 (23), 3949-3951.
13.
14.
15.
16.
17.
18.
19.
20.
21.
Kozlov V.V., Nuno J., and Wabnitz S. (2011): Theory of
lossless polarization attraction in telecommunication fibers, J.
Opt. Soc. Am. B, 28 (1), 100-108.
Kozlov V.V., Nuno J., Ania-Castanon J. D., and Wabnitz S.
(2010): Theory of fiber optic Raman polarizers, Opt. Lett., 35
(23), 3970-3972.
T. Golubeva, Yu. Golubev, K. Samburskaya, C. Fabre, N.
Treps, M. Kolobov. Entanglement measurement of the
quadrature components without the homodyne detection in the
spatially multi-mode far-field. Phys. Rev. A 81(1), 013831,
2010.
Manshina A., Povolotskiy A., Ivanova T., Kurochkin A.,
Tver’yanovich Yu., Kim D., Kim M., Kwon S.C. Laser-assisted
metal deposition from CuSO4-based electrolyte solution //
Laser Phys. Lett., 4, №2, (2007) P.163 – 167.
Manshina A., Povolotskiy A., Ivanova T., Kurochkin A.,
Tver’yanovich Yu., Kim D., Kim M., Kwon S.C. CuCl2-based
liquid electrolyte precursor for laser-induced metal deposition
// Laser Phys. Lett., 4, №3, (2007) P.242 – 246.
Manshina A., Povolotskiy A., Ivanova T., Kurochkin A.,
Tver’yanovich Yu., Kim D., Kim M., Kwon S. Laser-induced
copper deposition on the surface of an oxide glass from an
electrolyte solution // Glass Phys. and Chem., Vol. 33, № 3,
(2007) P. 209 – 213.
Manshina A.A., Povolotskiy A.V., Ivanova T.Y., Kurochkin A.V.,
Tver’yanovich Y.S., Kim D., Kim M., Kwon S.C. Effect of salt
precursor on laser-assisted copper deposition // Appl. Phys.
A, DOI: 10.1007/s00339-007-4164-9, 2007.
Manshina A., Ivanova T., Povolotskiy A., Tveryanovich Yu, S.K. Liaw, Y.-S. Hsieh. Erbium-mediated photoconductivity of
Ga–Ge–S–Se: Er3+ chalcogenide glasses. J.Phys. D: Appl.
Phys. 41 (2008) 175110.
S.-K. Liaw, K. -L. Hong, G. -S. Jhong, T. Yu. Ivanova, A. A.
Manshina, Yu. S. Tveryanovich. Pump slope-improved fiberring laser by recycling the residual pumping power. Laser
Physics 18, 2008, p. 1040
37
A. Povolotskiy, T. Ivanova, A. Manshina, Y. Tver’yanovich ,
Shien-Kuei Liaw ,Chu-Lin Chang. Er3+ as glass structure
modifier of Ga–Ge–S chalcogenide system. Appl Phys A
(2009) 96: 887–891.
Manshina A., Ivanova T., Povolotskiy A. Laser-induced
deposition of hetero-metallic structures from liquid phase //
Las. Phys., V. 20 (6), 2010, P. 1532-1536.
Liaw, S.K., Wang, S., Shin, C.S., Yu, Y.L., Chen, N.K., Hsu,
K.C., Manshina, A., Tver'Yanovich, Y. Linear-cavity fiber laser
using subring-cavity incorporated saturable absorber for
single-frequency operation. Laser Physics 2010, 20 (8), pp.
1744-1746
Liaw, S.K., Wang, S., Shin, C.S., Chen, N.K., Hsu, K.C.,
Manshina, A., Tver'Yanovich, Y., Wang, L.K. Singlelongitudinal-mode linear-cavity fiber laser using multiple
subring-cavities, Laser Physics 2010, 20 (7), pp. 1608-1611
22.
23.
24.
25.
Selected Projects
38
Effective generation of quasi-monochromatic X-ray
radiation using extra-power femtosecond laser pulses
and nanosized targets Prof.Rozanov N.N., Prof. Andreev
A.A., Dr. Venediktov V.Yu RFBR 09-02-12129
Search for new sources of entangled light for quantum
optics and quantum information. Prof. Yu.M.Golubev, Joint
RFBR-CNRS grant 05-02-19646, 2006-2008
Theoretical development of parallel quantum memory for
images and spatially multimode sources of non-classical
light. Prof. I.V.Sokolov, RFBR grant 08-02-00771-a, 20072010
High Dimensional Entangled Systems (HIDEAS). Prof.
I.V.Sokolov, EU FP7 programme Collaborative Project n.
221906, 2008-2011
Entanglement and squeezing in high-dimensional
quantum systems. Dr. T.Yu. Golubeva, Joint RFBR-CNRS
grant 08-02-92504, 2008-2011
General Physics II (Chemical Physics)
Professor Valentin I. Korotkov, Head of the Department
M.Sc. 1971, Ph.D. 1976, D.Sc. 1997
Research staff: Prof. Dr. Vladimir E. Kholmogorov; Prof. Dr. Victor
L. Rapoport; Dr. Alexander V. Barmasov; Dr. Elena P.
Zarochentseva; , Dr. Sofia O. Vysotskaya, Dr. Irina S. Bobkova; Dr.
Tatyana N. Kompaniets; Dr. Tamara V. Rudakova; Dr. Boris D.
Katunin; Dr. Stanislav V. Ascheulov; Dr. Dmitriy A. Lisachenko.
D. Sc. Ilya G. Shenderovich; Dr. Larisa N. Baranova; Dr. Vladimir M.
Malkin; M.Sc. Vladimir V. Goruchko
Units:
Physics
Biomolecular and Chemical Physics
39
Basic special courses for students
General Physics
Conceptions of Modern
Science
History of Physics
Chemical Physics
Physics of macromolecules
Photonics of biomolecules
Research topics
Photochemistry.
Biophysics.
Photophysics.
Polymer Chemistry and
Physics.
Photoprocesses in
interfacial complicated
molecules
Free radical processes
and methods of its
studies
Kinetics of surface
processes
Photo/Solar Energy.
Environmental Chemistry.
Magnetic-Spin Chemistry.
Nuclear Magnetic
Resonance.
Special equipment
Spectrophotometers.
Spectrofluorimeter.
EPR-spectrometers.
Mass-spectrometers.
Partner
Free University of Berlin
Monograph
1. “Self-organization of complex molecules. Properties of
structures of different levels organization” Ed. V.I. Korotkov.
St.Petersburg State University (2008) 242p,
2. Grishchenko A.E., Kononov A.I., Michailova N.A., Naumova
L.V. “Self-Organisation of polymer molecules in interfacial”
St.Petersburg State University, (2010) 197p
40
Selected papers
1.
V.I. Korotkov Mathematical models in chemical physics and
combustion theory. In Encyclopaedia of Life Support Systems
(EOLSS), Developed under the auspices of the UNESCO,
Eolss Publishers, Oxford, UK, (2006). [http://www.eolss.net ]
2.
Surface
nanocrystal
hydrogen-bonded
complex
for
photochemical water splitting V.I. Korotkov, I.A. Akimov, S.O.
Visotskaya, A.A. Evstrapov, .N. Jasnikov. Journal of
Photochemistry and Photobiology, A: Chemistry V 196 (2008),
138-142.
3.
Investigation of adsorption of 2,2'-bipyridine on МСМ-41 silica
matrix by NMR 15N spectroscopy. S.B. Lesnichin, N. Kamdem,
D. Mauder, G. S. Denisov, I.G. Shenderovich. Russian J. Gen.
Chem. (2010) 80, 1718-1722.
4.
‘Counteranion-Dependent Mechanisms of Intramolecular
Proton Transfer in Aprotic Solution. S.B. Lesnichin, P.M.
Tolstoy, H.-H. Limbach, I.G. Shenderovich Phys. Chem. Chem.
Phys. (2010) 12, 10373-10379.
5.
NMR Study of Proton Transfer to Strong Bases on Inner
Surfaces of MCM-41 B.C.K. Ip, D.V. Andreeva, G. Buntkowsky,
D. Akcakayiran, G.H. Findenegg, I.G. Shenderovich Micropor.
Mesopor. Mater. (2010) 134, 22-28.
6.
Density Functional Study of the Proton Transfer Effect on
Vibrations of Strong (Short) Intermolecular O-H· · N/O-· ·H-N+
Hydrogen Bonds in Aprotic Solvents S. Kong, I. G.
Shenderovich, M. V. Vener J. Phys. Chem. A (2010) 114,
2393–2399.
7.
D. Mauder, D. Akcakayiran, S. B. Lesnichin, G. H. Findenegg,
I. G. Shenderovich Acidity of Sulfonic and Phosphonic
Acid-Functionalized SBA-15 under Almost Water-Free
Conditions J. Phys. Chem. C (2009) 113, 19185-19192.
41
8.
9.
10.
11.
12.
13.
14.
15.
42
I. Alkorta, J. Elguero, H.-H. Limbach, I.G. Shenderovich, T.
Winkler A DFT and AIM analysis of the spin-spin couplings
across the hydrogen bond in the 2-fluorobenzamide and
related compounds Magn. Reson. Chem. (2009) 47, 585–592.
N.S. Golubev, C. Detering, S.N. Smirnov, I.G. Shenderovich,
G.S: Denisov, H.-H. Limbach, P.M. TolstoyH/D isotope effects
on NMR chemical shifts of nuclei involved in a hydrogen bridge
of hydrogen isocyanide complexes with fluoride anion Phys.
Chem. Chem. Phys. (2009) 11, 5154-5159.
N.S. Golubev, G.S. Denisov, S. Mcholl, S.N. Smirnov, I.G.
Shenderovich, P.M. Tolstoy. NMR study of blue-shifting
hydrogen bonds formed by fluoroform in solution Z. Phys.
Chem. (2008) 222, 1225-1245.
I.G. Shenderovich, D. Mauder, D. Akcakayiran, G. Buntkowsky,
H.-H. Limbach, G.H. Findenegg. NMR provides checklist of
generic properties for atomic-scale models of periodic
mesoporous silicas J. Phys. Chem. B (2007) 111, 1208812096.
S. Sharif, I.G. Shenderovich, L. González, G.S. Denisov, D.N.
Silverman; H.-H. Limbach. NMR and Ab initio Studies of Small
Complexes Formed between Water and Pyridine Derivatives in
Solid and Liquid Phase J. Phys. Chem. A (2007) 111, 60846093.
I.G. Shenderovich Qualitative Analysis of the Geometry of the
Hydrogen Bond in the Homoconjugated Pyridine Ion Russian
J. Gen. Chem. (2007) 4, 620-625.
A. Vyalikh, Th. Emmler, I. Shenderovich, Y. Zeng, G.H.
Findenegg, G. Buntkowsky 2H-solid state NMR and DSC study
of isobutyric acid in mesoporous silica materials Phys. Chem.
Chem. Phys. (2007) 9, 2249–2257.
D.V. Andreeva, B. Ip, A.A. Gurinov, P.M. Tolstoy, I.G.
Shenderovich, H.-H. Limbach Geometrical features of
hydrogen bonded complexes involving sterically hindered
pyridines. J. Phys. Chem. A (2006) 110, 10872-10879.
16.
17.
18.
19.
20.
21.
22.
I.G. Shenderovich Maximum Value of the Chemical Shift in the
1
H NMR Spectrum of a Hydrogen-Bonded Complex. Russian J.
Gen. Chem. (2006) 76, 501-506.
Grishchenko A.E., Michailova N.A.,Naumova L.V.,Gubarev
A.S., Makarova N.N. Study of orientational in thin films of
disklike heptameric polycyclosiloxane molecules by means of
the oblique-polarised-ray method. J. of Optical Technology
(2005) V.72 Issue 1, 15-19.
Shtennikova I.N., Grishchenko A.E., Michailova N.A., Kolbina
G.F., Khotimskii V.S. The studies of Molecular strucrure poly
(1-trimethylsilyl-1-propyne) stereoisomers
by the flow
birefrengence method. European polymer J. (2006) V42, N6,
1325-1329.
GrishchenkoA.E, Khudyakova O.V., Michailova N.A.,Gubarev
C.A., Ionov A.N. Molecular characteristics and surface layer
structure of poly (siloxane imides) Polymer Sci Ser A. (2007)
V49, N5, 532-537.
GrishchenkoA.E, Roizard D., Petrakov A.P., Mikhailova N.A.,
Molecular Structure and Morfology of memrane-Forming
Copolymers of tolylene dinrea and poly(dimethylsiloxane)
Polymer Sci Ser A. (2007) V49, N5, 571-577.
GrishchenkoA.E., Kononov A.I., Michailova N.A., Makarova
N.N., Сhizhova N.V., Zaitseva I.I. Self-Organisation and SelfAssocition of Pentameric Polyorganocyloxane Molecules at
the Interface: a Study by the inclined Polarized Beam Method.
Doklady Pysical Chemistry. (2008) V.241, Part 1, 179-181.
V.M. Malkin, V.L. Rapoport. Photochemical detection of the
stacking aggregation of thymine chromophores in aqueous
solutions of polythymidylic acid. Biophysics, (2005) Vol. 50, No, 6
874-878.
43
23.
24.
44
V.L. Rapoport, V.M. Malkin, S.V. Zorina, S.M. Komarov, and
V.V. Goryuchko. Luminescence detection of tightly bound
stacking aggregates of adenine and adenosine in aqueous
solutions – the candidates for the role of the first genetic
templates. Doklady Biochemistry and Biophysics. (2006) Vol.
406, 23-26.
V.M. Malkin, V.L. Rapoport. A study of the spectral and
luminescence manifestations of the aggregation of thymine
chromophores in polythymidylic acid aqueous solutions at room
temperature in the context of photochemical information
recording using thymine, Biophysics (2008) Vol. 53 No. 5 336340.
Selected Projects
Investigation of a role of physical and chemical factors in
self-organizing of chain molecules on phase boundaries.
Prof. A.E. Grischenko, Grant RNP № 2.1.1. 4139, 2006-2008
Investigation of long-living electron states and energy
transfer in organic polycrystals. Prof. V.I. Korotkov,
Contract, 2008-2009
Investigation of influence of electromagnetic fields of
different frequency ranges on organic nanostructures
and alive systems. Sen. Res. V.E. Stefanov, Grant RNP №
2.1.1.485 2009-2010.
Photonics
and
spintronics
of
low-dimensional
condensed phases for informational technology. Prof.
A.A. Tzyganenko, Grant NPK, 2009-2013.
Physical and chemical investigation of given
polycrystalline structures. Prof. V.I. Korotkov, Contract,
2010-2012.
Photophysics of complex organic and biological
molecules. Prof. V.I. Korotkov, Grant SpbSY № 26.11.2010,
2010-2014.
Characterization of the structure and dynamics of
mesoporous host-guest materials using solid state NMR
techniques. Principal Investigators: Prof. Dr. H.-H. Limbach
and Dr. I. Shenderovich. Grant DFG (German Research
Foundation) 2007-2009.
Solid state NMR studies of cofactor-protein systems with
functional hydrogen bonds Principal Investigators: Prof. Dr.
H.-H. Limbach, Dr. G. Buntkowsky and Dr. I. Shenderovich
Grant DFG (German Research Foundation) 2006-2008.
Investigation of geometry of functional hydrogen bonds
in solutions by NMR/IR/UF spectroscopy. Sen. Res. I.G.
Shenderovich, Grant RFBR 09-03-91336, 2009-2011.
45
46
Luminescence and quantum chemical study of tightly
bound stacking aggregates of adenine and uracil in
connection with modelling of first stages of chemical
evolution. Prof. V. L. Rapoport . State Contract with Institute
of Cytology RAS. 2007.
Luminescence and quantum chemical modelling of first
stages of chemical evolution in systems adenine+uracil
and adenine+thymine. Prof. V. L. Rapoport . State Contract
with Institute of Cytology RAS. 2008.
Luminescence and quantum chemical study of first
stages of chemical evolution including tightly bound
stacking aggregates of nucleic bases. Prof. V. L. Rapoport
. State Contract with Institute of Cytology RAS. 2009.
Luminescence study of first stages of chemical evolution
with participation of tightly bound stacking aggregates of
adenine and uracil. Prof. V. L. Rapoport . State Contract
with Institute of Cytology RAS. 2010.
Mathematics and Mathematical Physics
Professor Vladimir S. Buslaev, Head of the Department
M.Sc. (1959), Ph.D. (1962), D.Sc. (1973)
Selected staff members
Prof. Vladimir S. Buslaev, the Head of the Department; Prof. Ludvig
D. Faddeev, fellow of the Russian Academy of Sciences. Full
professors: Boris A. Plamenevsky, Natalia V. Smorodina, Tatiana A.
Suslina, Mikhail A. Lyalinov, Mikhail I. Belishev, Alexei P. Kiselev,
Mikhail V. Babich, Eugeny L. Korotyaev. Leading research fellow:
Serguei N. Naboko. Associate Professors: Alexander S.
Blagoveschensky, Alexander M. Budylin, Ludmila A. Dmitrieva,
Maria V. Perel, Oleg V. Sarafanov, Vladimir V. Sukhanov, Mikhail M.
Faddeev, Alexander A. Fedotov, Nikolai D. Filonov, Alexei L.
Pirozersky, Vladimir A. Sloushch, Alexander V. Kiselev, Roman V.
Romanov. Senior lecturers: Alexei N. Popov, Natalia G. Gelfreih,
Alexei A. Pozharsky. Assistant Professor: Sergey A. Simonov.
47
Major teaching areas
Physics, radiophysics, applied mathematics and physics.
M.Sc. Programme profile
Theoretical and mathematical physics 010700/17 (programme No.
25 – problems of mathematical and computational physics)
Selected lecture courses
General courses
1. Mathematical analysis.
2. Algebra.
3. Methods of mathematical physics.
4. Probability theory.
Special courses.
1. Function theory.
2. Functional analysis.
3. Manifold geometry.
4. Spectral theory of linear operators.
5. Asymptotic methods for ordinary differential equations.
6. Lie groups and algebras.
7. Sobolev spaces and their applications.
8. Ray method in the wave propagation theory.
9. Scattering theory.
10. Spectral theory of partial differential operators.
11. Markov processes and their applications.
12. Spectral theory of ordinary differential operators.
13. Pseudo-differential operators and boundary value problems.
14. Canonical problems of wave propagation theory.
15. Inverse problems in wave propagation theory.
16. Non-linear integrable systems.
48
Main research areas
Spectral theory of differential operators: Maxwell operator,
Schrodinger operator, operators with periodic coefficients,
Weyl asymptotics, absolute continuity of the spectrum.
Homogenization of periodic differential operators. Operator
estimates of the error. Homogenization in the scattering
problems.
Few-body scattering. Coulomb potentials, singularities of the
scattering matrix.
Spectral properties and the behavior of solutions of onedimensional almost-periodic Schrodinger operators. Behavior
at infinity of solutions to equations with analutic potentials of
general form and with large coupling constant.
Behavior of exponential sums with large numbers of terms.
Mathematical problems of the wave propagation theory in
non-homogeneous waveguides (electronic, electromagnetic,
acoustical). Development of asymptotic and numeric
methods. Applications to nano- and microelectronics.
The theory of hyperbolic initial-boundary value problems in
domains with singularities, in particular, development of
asymptotical methods. Applications to dynamical problems of
elasticity theory and flaw theory. Pseudo-differential
operators on manifolds with singularities.
Mathematical methods in scattering of acoustic and
electromagnetic waves in domains with conic and wedge-like
singularities of the boundary, asymptotic methods in the
mathematical theory of diffraction, function-difference,
integral equations and their applications in the wave
propagation theory.
Investigations in the area of probability theory and stochastic
analysis – theorems on the convergence of stochastic
integral distributions, probabilistic representations of solutions
to differential equations.
49
Inverse spectral problems for ordinary differential equations.
Investigation of asymptotic behavior of solutions to non-linear
integrable equations.
Spectral analysis of Hermitian Jacobi matrices.
Mathematical theory of elastic surface waves. The theory of
optical beams and bundles.
Multidimensional dynamical and spectral inverse problems.
Problems on manifolds. Inverse problems for multi-velocity
systems. Problems on graphs. Connections between inverse
problems and control theory, systems theory, operator theory
and C*-algebras.
Permanent collaboration with foreign universities and
institutes.
Paris 13 University, Laboratory of algebra, geometry,
analysis and applications.
Bath University, UK.
University of Sannio in Benevento, Italy.
Institute of High Frequency Technique, Stuttgart University,
Germany.
CEA (Commissariat Energy Atomique), France.
Bohn University, Germany.
UAB – University of Alabama at Birmingham.
University of Cardiff, UK.
Institute of Mathematics, Polish Academy of Sciences,
Krakow.
Institute of Mathematics, National Academy of Sciences,
Ukraine.
Bordeaux 1 University, France.
Valladolid University, Spain.
Department of applied analysis of the Higher School of
Informatics, University of Kyoto, Japan.
Department of Mathematical Information technology,
Jyväskylä University, Finland.
50
Monographs
M.Sh. Birman, M.Z. Solomyak. Spectral theory of selfadjoint operators in Hilbert spaces. 2nd edition. Lan',
St.Pb., 2010.
M.Sh. Birman. Selected papers. Mathematical scattering
theory. Spectral shift function. RHD, Moscow-Izhevsk,
2010.
L.D. Faddeev, O.A. Yakubovskii. Lectures on quantum
mechanics for mathematics students. AMS, Providence,
RI. 2009, 234.
L.D. Faddeev, L. Takhtajan, Hamiltonian methods in
theory of solitons, Berlin: Springer, 2007.
1. V.M. Babich, M.A Lyalinov, V.E. Grikurov: Diffraction Theory.
The Sommerfeld-Malyuzhinets Technique, Alpha Science
Ser. Wave Phenom. (Alpha Science, Oxford 2008).
2. Pseudo-differential operators on piecewise-smooth
manifolds. Tamara Rozhkovskaya publishers, Novosibirsk,
2010.
3. A.A. Fedotov. Complex WKB method for adiabatic
perturbations of periodic operators with applications
towards the study of the spectrum of almost-periodic
operators. To appear in: London Math Society Lecture Notes
Selected research papers
1. L.D. Faddeev, A.J. Niemi, Spin-charge separation,
conformal covariance and the SU(2) Yang–Mills theory,
Nuclear Physics B, v. 776, Issues 1-2, (2007), Pages 38-65.
2. L.D . Faddeev, M.N. Chernodub A.J. Niemi Non-abelian
supercurrents and de Sitter ground state in electroweak
theory, J. High Energy Phys. (2008), 0812-014.
3. L.D. Faddeev, Discrete series of representations for the
modular double of the quantum group U_q(sl(2,R)),
Functional Analysis and Its Applications, Volume 42, Number
4, 330-335.
51
4. L.D. Faddeev, Volkov, A.Yu. Discrete evolution for the
zero modes of the quantum Liouville model, Journal of
Physics A Mathematical and Theoretical (2008),41 (19),
art.no. 194008.
5. L.D. Faddeev Notes on divergences and dimensional
transmutation in Yang-Mills theory, Theor. Math.
Phys.(2006)Vol. 148(1), pp. 986-994.
6. M.Sh.Birman, T.A.Suslina, Operator error estimates in the
homogenization problem for nonstationary periodic
equations, Algebra i Analiz, vol. 20 (2008), no. 6, 30-107;
English transl., St.Petersburg Math. J., vol. 20 (2009), no. 6,
873-928.
7. T.A.Suslina, Homogenization in the Sobolev class H1(Rd)
for second order periodic elliptic differential operators
with the inclusion of first order terms, Algebra i Analiz,
vol. 22 (2010), no. 1, 108-222; English transl., St.Petersburg
Math. J., vol. 22 (2011), no. 1, 81-162.
8. V.S.Buslaev and S.B.Levin, Asymptotic behavior of the
eigenfunctions
of
many-particle
Schr\"{o}dinger
operator.~I. One-dimensional particles; in: Selected
topics in mathematical
physics, Dedicated to Prof.
Mikhail Shl\"emovich Birman on his 80th birthday, Amer.Math.Soc.Transl. (2)v.225, pp.55-71, (2008)
9. V.S.Buslaev, S.B.Levin, P.Neittaannmaki, T.Ojala
New
approach to numerical computation
of the
eigenfunctions of the continuous spectrum of threeparticle Schrodinger operator. I One-dimensional
particles, short-range pair potentials.. J.Phys.A:
Math.Theor. 43, (2010), 285205, (pp.17); arXiv:0909.4529v1
[math-ph], (2009).
10. L.Baskin, P.Neittaanmäki, B.Plamenevskii, O.Sarafanov,
Asymptotic theory of resonant tunneling in 3D quantum
waveguides of variable cross-section, SIAM Journal on
Appl.Math., 70(2009), no.5, 1542-1566.
11. Lyalinov M.A., Acoustic scattering of a plane wave by a
circular penetrable cone, Wave Motion, V. 48, pp. 62-82,
(2011).
52
12. Lyalinov M.A., N.Y. Zhu and V.P. Smyshlyaev, Scattering of
a plane electromagnetic wave by a hollow cone with thin
semi-transparent walls, IMA Journal of Applied Mathem., V.
75, pp. 676-719, (doi:10.1093/imamat/hxq030), (2010).
13. N.
Smorodina,
M.Faddeev.
The
Levy-Khinchin
representation of the one class of signed stable
measures and some its applications. Acta Appl. Math. DOI
10.1007/s10440-009-9510-9
14. S.Albeverio, N.Smorodina A Distributional Approach to
Multiple Stochastic Integrals and Transformations of the
Poisson Measure Acta Appl. Math. (2008) 102, 319-343;
DOI 10.1007/s10440-008-9223-5
15. Laptev A., Östensson J.,Shterenberg R. and Sukhanov V.
Reflectionless potentials for an ordinary differential
operator of order four. Inverse Problem, 22 (2006), pp.135153.
16. M.Sh. Birman, N. Filonov, Weyl's asymptotics of the
spectrum of the Maxwell operator with non-smooth
coefficients in Lipschitz domains. Amer. Math. Soc.
Transl., Vol. 220, no. 2, P. 27-44, 2007.
17. Perel, M. V., and M. S. Sidorenko, Wavelet-based integral
representation for solutions of the wave equation,
Journal of Physics A: Mathematical and Theoretical, 42,
3752-3763, 2009.
18. Perel, M. V., and M. S. Sidorenko,, New physical wavelet
'Gaussian wave packet', Journal of Physics A: Mathematical
and Theoretical, 40(13), 3441-3461, 2007.
19. Kurasov P.,Naboko S. Wigner-von Neumann perturbations
of a periodic potentials: spectral singuliarities in bands.
Math. Proc. Cambrige Phyl.Soc. 142 (2007),no.1, 161-183.
20. Janas J.,Naboko S.,Stolz G. Decay bounds of
eigenfunctions and the singular spectrum of unbounded
Jacobi matrices.,Int.Math.Res. Notes, IMRN (2009),no.4,736764.
53
21. A.P. Kiselev, Localized light waves: Paraxial and exact
solutions of the wave equation (a review) Optics and
Spectroscopy, 2007, Volume 102, Number 4, Pages 603-622
22. I.V. Kamotskii and A.P. Kiselev, "An energy approach to the
proof of the existence of Rayleigh waves in an
anisotropic elastic half-space," J. Appl. Math. Mech. 73
(4), 464-470 (2009)
23. A.P.Kiselev,
D.F.Parker. Omni-directional Rayleigh,
Stoneley and Scholte waveswith general time
dependence. Proc. Roy. Soc. London, Ser. A, 466(2120),
2241-2258, 2010
24. M.I.Belishev. Recent progress in the boundary control
method. Inverse Problems, 23 (2007), No 5, R1--R67.
25. M.I.Belishev and V.A.Sharafutdinov. Dirichlet to Neumann
operator on differential forms. Bulletin de Sciences
Mathematiques, 132 (2008), No 2, 128--145.
26. R. Romanov, On the concept of absolutely continuous
subspace for nonselfadjointoperators, J. Oper. Theory,
vol. 63 (2010), No. 2, 375 – 388.
54
Molecular Biophysics
Research staff: Prof. Pavel Vorontsov-Veliaminov , Prof. Vladislav
Professor Anatoli Trusov, Head of the Department
M.Sc. 1962, Ph.D. 1967, D.Sc. 1982
Vojtulov, Prof.. Nina Kasianenko. Dr. Igor Kochnev, Dr. Alexander
Polianichko, Dr. Sofia Paston, Dr. Alexei Voitulov, Dr. Alexei
Kholoimov, Dr. Ludmila Shurupova, Dr. Vladimir Bakulev, Dr. Maja
Sibileva, Dr. Evgenia Moroshkiha Dr. Yurchenko, Dr. Alexei
Kononov, Dr. Yurchenko, Dr. Poliakov, Dr. Mercurieva.
Educational direction:
Physics profiles:
Molecular Biophysics, Molecular Optics.
Applied
Mathematics and Physics profile:
Nanobiophysics
55
The main courses:
Methods of biological
macromolecules
investigations
Molecular biophysics
Conformation of polymers in
а solution
Molecular biology
Radiation biology
Interaction of
macromolecules with ligands
Quantum chemistry
Methods of nanosystems
investigations
Electrooptics of solutions
Theory of polyelectrolytes
Methods of mathematical
experiment
Interaction of nucleic acids
with proteins
Radio-frequency
spectroscopy
Introdaction to genetic
engineering
Photobiology
Nanosystems visualization
methods
Additional chapters of
molecular spectroscopy
Laser spectroscopy.
Spectroscopy of optical
merging.
Diffraction experiments on
liquids
Methods of molecular
dynamics
Constant cooperation with foreign high schools or institutes:
Stockholm University (Sweden), Department of Material and
Environmental Chemistry, Division of Physical Chemistry
University of Nebraska (USA), Medical Center
University of Freiburg (Germany), Institute for Microsystem
Technology (IMTEK)
University of Postdam (Germany)
Research topics:
Elecrtrooptics and conductometry of disperse and biodisperse
systems.
Electrokinetic properties of colloids and biocolloids.
DNA Interaction With Biological Active Compounds inSolution
DNA-Polymeric Complexes
Polyelectrolyte Properties of DNA
Structure of DNA Reversible Complexes with Biological Active
Ligands
56
Structural Changes of DNA and Medical Supplying Synthetic
Polymers under Influence of Environment Properties and
During Interaction with Fullerenes and Phthalocyanines
Free energy calculations for polymer and other molecular
systems with the aid of Monte Carlo expanded ensemble
method.
Simulation and analytical studies of small and mesoscopic
quantum particle systems at finite temperatures.
Molecular dynamics in water solutions of proteins and
peptides by IR spectroscopy.
Study of molecular structure and dynamics in polymers,
plastic and liquid crystals, biomolecular systems by NMR
spectroscopy.
Molecular dynamics and intermolecular correlations in the
disordered systems by the method of light scattering
Invironment and radiation effects on the luminescence of
biopolymers and related molecules.
Selected papers:
1. A.A.Trusov, V.V.Vojtylov "Electrooptics and Conductometry of
Polydisperse Systems" 1993, CRC Press, Boca Raton Ann Arbor
London Tokyo.
2. A. Melnikov, A. Spartakov, A. Trusov, V. Voitulov. Complex
electrooptic research of nano-particle in colloids, Colloids and
Surfaces B, 2007, v. 56, p. 65-71.
3. A. Spartakov, A. Trusov, A. Voitylov, V. Vojtylov. ” Electro-Optics
of Polydisperse Colloids”/in the book “Molecular and Colloidal
Electro-Optics”, Surfactant science series volume 134, chap.7,
CRC Taylor & Francis, 2007, p. 193-227.
4. L. K. Babadzhanyants, A. V. Voitylov, V. V. Voitylov, and A. A.
Trusov, Analysis of Polydispersity of Macromolecular and
NanodisperseSystems by Electrooptical Methods Polymer
Science, Ser. C, 2010, Vol. 52, No. 1, pp. 93–104.
5. S.A. Klemeshev, M.P. Petrov, A.A. Trusov and A.V. Voitylov.
Electrooptical effects in colloid systems subjected to short
pulses of strong electric field. J. Phys.: Condens. Matter 22
(2010) 494106 (10pp)
57
6. Kasyanenko N., Zanina A., Nazarova O., Panarin E. DNA
Interaction with Complex Ions in Solution. Langmuir, 1999, v.15,
n 23, p.7912-7917
7. I. Turel, E. Morozova, V. Baculev, N. Kasyanenko, Jo Ann W. Byl, N.
Osheroff. First Ruthenium Organometallic Complex of Antibacterial
Agent Ofloxacin. Crystal Structure and Interactions with DNA.
Inorg. Chem., 2010, 49, 23, pp 10750–10752
8. N.A. Kasyanenko., E.V. Levykina., O.S. Erofeeva., N.A. Ivanova.,
I.A. Efimenko Study of influence of palladium acidocomplexes
[Ln]m[PdX4] on DNA conformation in vitro Journal of Structural
Chemistry; 2009, N 5, p. 1034-1044
9. A. Puchkova, P. Sokolov, Y. Petrov and N. Kasyanenko.
Metallization of DNA on silicon surface Journal of Nanoparticle
Research, 2011, 1-9
10. N.A. Kasyanenko, D. A. Afanasieva, B. A. Dribinsky, D. V. Mukhin,
O. V. Nazarova, and E.F. Panarin. DNA interaction with synthetic
polymers in solution. Struct. Chem, 18(4), 519-525, (2007).
11. Moroshkina E.B., Bogdanov A.A.,Kolonistova M.O., Sedova
O.B., Urusova T.A.
Theeffect of counterion nature in solution
on the DNA interaction with derivativesof phenoxasone, xantone
and carbasol containing benzo-crown-fragments. Journal of
Structural Chemistry,2009, V. 50, №5, P. 989-995.
12. Polyanichko. A.M., Andrushchenko V.V., Bouř P., Wieser H.
(2011) Vibrational circular dichroism studies of biological
macromolecules and their complexes. In: “Circular Dichroism:
Theory and Spectroscopy”, Edited by David S. Rodgers, Nova
Science Publishers, Inc., New York, USA, 2011, pp. (ISBN: 9781-61122-522-8)
13. Tsankov D., Polyanichko A., Wieser H. (2010) Vibrational
Circular Dichroism: Ensuring Quality of Pharmaceutical
Products, In: “Handbook of Analysis and Pharmaceutical
Quality. Pharmaceutical Sciences Encyclopedia: Drug
Discovery, Development, and Manufacturing”, Edited by Shayne
C. Gad, John Wiley & Sons, Inc, 1-41. (Online ISBN: 978-04705-7122-4).
58
14. Chikhirzhina E.V., Polyanichko A.M., Kostyleva E.I., Vorobyev
V.I. (2011) Structure of DNA Complexes with Chromosomal
Protein HMGB1 and Histone H1 in the Presence of Manganese
Ions. 1. Circular Dichroism Spectroscopy. Molecular Biology.
45(2), 318-326.
15. Polyanichko A.M., Rodionova T.J., Vorob’ev V.I., Chikhirzhina
E.V. (2011) Conformational Properties of nuclear protein
HMGB1 and Specificity of Its Interaction with DNA. Cell and
Tissue Biology. 5(2), 114-119.
16. A.A. Mercurieva, P. Iakovlev, E.B. Zhulina, T.M. Birshtein,
F.A.M. Leermakers Wetting Phase Diagrams of a Polyacid
Brush with a Triple Point. Physical Review E, 2006 .74, 031803031813
17.
A.A. Mercurieva, T.M. Birshtein, F.A.M. Leermakers Modeling
of Charged Amphiphilic Copolymer Stars near Hydrophobic
Surfaces Langmuir, 2009, 25 (19), 11516-11527
18. Volkov N. A., Yurchenko A. A., Lyubartsev A. P., VorontsovVelyaminov P. N. Entropic sampling of free and ring polymer
chains. Macromolecular Theory and Simulation, 14, 491-504
(2005).
19. Broukhno A. V., Vorontsov-Velyaminov P. N., Bohr H. A
Polymer Density Functional Theory to Efficiently Evaluate Path
Integrals: Application to Atoms. Physical Review E, 72, 046703
(2005) .
20. Vorontsov-Velyaminov P.N., Voznesenski M.A., Malakhov
D.V., Lyubartsev A.P., Broukhno A.V. Path integral method in
quantum statistics problems: general ensemble Monte Carlo and
density functional approach. Journal of Physics A: Math. &
General, 39, 4711-4716 (2006).
21. Volkov N.A., Vorontsov-Velyaminov P.N., Lyubartsev A.P.
Entropic sampling of flexible polyelectrolytes within WangLandau algorithm. Phys.Rev. E (2007) 75, 016705 – 1-10.
22. Mikhail A. Karymov, Alexey Bogdanov, Yuri L. Lyubchenko
Single Molecule Fluorescence Analysis of Branch Migration of
Holliday Junctions: Effect of DNA Sequence. Biophysical
Journal, 2008, v. 95, 3, 1239-1247.
59
23. M. A. Karymov, M. Chinnaraj, A. Bogdanov, A. R. Srinivasan, G.
Zheng, W. K. Olson, and Y. L. Lyubchenko Structure, Dynamics,
and Branch Migration of a DNA Holliday Junction: A SingleMolecule Fluorescence and Modeling Study Biophysical
Journal,2008, v. 95, 9, 4372 – 4383.
24. Pavlov G.M., Gubarev A.S., Zajtseva I.I., Sibileva M.A. About
the definition of intrinsic viscosity value of polyelectrolitic
molecules
in saltless solutions.J. Appl. Chem., 79, No.
9(2006)1423-1428.
25. I.N. Kochnev Anharmonic dynamics: melting and mass
transfer in liquid. Physica B, 373, 217-228, (2006).
Selected projects
Simulation of molecular systems by generalized ensembles
Monte Carlo methods Prof. P.N. Vorontsov-Velyaminov, Grant
RFBR, 05-02-17428-а
Computer simulation of molecular nanosystems in the
framework of
classical and quantum statistics Prof. P.N.
Vorontsov-Velyaminov, Grant RFBR, 08-02-00041-а
Stochastic simulation of equilibrium properties and dynamics
of molecular systems in the framework of classical and
quantum statistics. Prof. P.N. Vorontsov-Velyaminov, Grant
RFBR, 11-02-00084-а
Anisotropic properties of disperse systems in magnetic field
and their connection with electric and magnetic properties of
colloidal particles Prof. A.A.Trusov, Grant RFBR, 05 - 03 32292а
Грант президента РФ (МК-2126.2007.4): Architectural aspects
of genome functioning by example of formation of
nanostructures in complexes of DNA with some chromatin
proteins (2007-2008). Dr. Polyanichko A.M.
Mechanisms of the self-assembling of structural-functional nanocomplexes based on the example of regulatory machinary of
chromatin (2009-2011) Dr. Polyanichko A.M., Grant RFBR, 09-0801119а
The effect of structural organization of the complexes of DNA with
HMGB-domain proteins on chromatin functioning (2010-2012) Dr.
Polyanichko A.M., Program of the Ministry of Science and Education of
the Russian Federation.
60
Molecular Spectroscopy
Professor Konstanin G. Tokhadze, Head of the Department
M.Sc. 1966, Ph.D 1974, D.Sc. 1991
Basic staff: Prof. D.Sc. M.O. Bulanin, Prof. D.Sc. S.F. Bureiko, Prof.
D.Sc. G.S. Denisov, Prof. D.Sc. N.N. Filippov,
Ass. Professors: Dr. V.P. Bulychev; Dr. M.V. Buturlimova, Dr. I.M.
Grigoriev; Dr. M.B. Kiseleva; Dr. S.M. Melikova, Dr. K.S. Rutkowski,
Dr. D.N. Shchepkin, Dr. I.K. Tokhadze, Dr. R.E. Asfin; Assist.
Professors: Dr E.I. Gromova
Senior Research.: Dr. V.V. Bertsev, Dr. T.D. Kolomiitsova, Dr. A.P.
Kouzov, Dr. Yu.M. Ladvishchenko, Dr. L.A. Zhigula, Dr. G.Ya.
Zelikina; Res.: V.N. Bocharov; A.V. Shuruhina.
Physics and Applied mathematics and physics
61
The field of research in the framework of the master programme:
" Theoretical and applied spectroscopy of molecular systems "
Lectures on a speciality
Fundamentals of the physics of molecules
Bulanin M.O.
Introduction to atomic and molecular spectroscopy Denisov G.S.
Electronic structure of molecules
Bulychev V.P.
Electronic spectra of molecules
Kiseleva M.B.
Experimental spectroscopy
Denisov G.S.
Vibrational and rotational spectra of molecules
Shchepkin D.N.
Physics of lasers
Rutkowski K.S.
Electro- and Magneto-optics of molecules
Shchepkin D.N.
Applied molecular spectroscopy
Denisov G.S.
Spectroscopy of molecular complexes
Tokhadze K.G.
Nature of intermolecular interactions
Grigor'ev I.M.
Laser and nonlinear optics
Bureiko S. F.
Profiles of spectral lines and bands
Filippov N.N.
Collision-Induced Spectra
Bulanin M.O.
High-Resolution Spectroscopy
Grigor'ev I.M.
Physics of Excited Molecules
Tokhadze K.G.
Vibration-Rotation spectra of polyatomic molecules Melikova S.M
Modern Methods of Calculation of Molecules and Bulychev V.P.
Complexes
Computer Simulation of crystals and fluids
Tokhadze I.K.
Spectra and molecular relaxation
Filippov N.N.
Research Topics
Molecular spectroscopy of real gases and condensed media
Spectroscopy and laser physics of molecules
Spectroscopy of cryogenic solutions and spectral band
shapes in dense fluids
Spectroscopic studies of molecular motion dynamics in
condensed and solid systems
Anharmonic spectroscopy of polyatomic molecule, vibrational
resonances
Collision induced infrared spectra of gases
Collision- indiced polarizabilities of atomic and molecular
species
Line-mixing effects in vibration-rotation spectra of simple
molecules
62
Spectroscopy of molecular complexes in pressurized gases,
cryogenic solutions and in low temperature matrices
Spectroscopy of systems with strong intermolecular interactions,
hydrogen bond and proton transfer
Molecular relaxation in the gas, liquid and solid states
Selected Papers
1. S.K. Ignatov, T.D. Kolomiitsova, Z. Mielke, A.G. Razuvaev, D.N.
Shchepkin, K.G. Tokhadze A matrix isolation and theoretical
study of SiF4 dimers spectra. Chemical Physics 324 (2006)
753 – 766.
2. R.E. Asfin, G.S. Denisov, K.G. Tokhadze The v(OH/OD) Band
Shape of Strong Hydrogen Bonded Dimers of Phosphinic
Acids. Phenomenology and Formation Models. J. Molec.
Struct. 790 (2006) 11-17.
3. A.V. Cherevatova, T.D. Kolomiitsova, D.N. Shchepkin, K.G.
Tokhadze, Z. Mielke, C. Coussan, P.Roubin Resonance DipoleDipole Coupling and Fermi Resonance in CF4 Dimers. J.
Molec. Spectr. 238 (2006) 64-71.
4. I.K. Tokhadze, T. D. Kolomiitsova, K. G. Tokhadze, D. N.
Shchepkin The Effect of Resonance Interactions on the
Absorption Spectra of (SF6)2 Dimers in Low-Temperature
Matrices. Calculations and Experiment. Optics and
Spectroscopy 102 (2007) 396–407.
5. M. Chrysos, F. Rachet, N.I. Egorova, A.P. Kouzov
Intermolecular
Raman
spectroscopy of
long-range
interactions: The CO2-Ar collision-induced ν3 CO2 band.
Phys. Rev. A, 75 (2007) 012707-10.
63
6. S. Sharif, G.S. Denisov, M.D. Toney, H.-H. Limbach NMR
Studies of Coupled Low- and High-Barrier Hydrogen Bonds
in Pyridoxal-5'-phosphate Model Systems in Polar Solution.
J. Am. Chem. Soc. 129 (2007) 6313-6327.
7. A.V. Domanskaya, M.O. Bulanin, K. Kerl, C. Maul Pressure
broadening and shifting parameters for the spectral lines in
the fundamental vibration-rotation bands of HBr and HI in
mixtures with rare gases. J. Mol. Spectrosc. 243 (2007) 155161.
8. V.P. Bulychev, E.I. Gromova, K. G. Tokhadze Study of the H-F
Stretching Band in the absorption Spectrum of (CH3)2O HF in
the gas phase. J.Phys. Chem. A, 112 (2008) 1251- 1260.
9. M. Chrysos, A.P. Kouzov, N.I. Egorova, F. Rachet. Exact LowOrder Classical Moments in Collision-Induced Bands by
Linear Rotors: CO2-CO2 . Phys. Rev. Lett. (2008) 133007-4.
10. M .V. Buturlimova, G.Ya. Zelikina, M.B. Kiseleva Solvent effects
on the ultraviolet absorption spectrum of mercury atom. J.
Mol. Struct. 880 (2008) 59-63.
11. K.S. Rutkowski, W.A. Herrebout, S.M. Melikova, B.J. Van der
Veken, A. Koll, A cryosolution FTIR and ab initio study of the
blue shifting C-H-F hydrogen bonded complexes
F2ClCH∙FCD3 and Cl2FCH∙FCD3. Chem. Phys.354 (2008) 71-79.
12. V.P. Bulychev, M.V. Buturlimova. Anharmonic calculation of
structural and vibrational properties of the isolated
complexes [F(HF)2]−, [F(DF)2]−, and [F(TF)2]−. J. Mol. Struct.928
(2009)32-39.
13. D.S. Andrianov, A.N. Cherevatova, T.D. Kolomiitsova, D.N.
Shchepkin Modeling of band shapes in the low-temperature
molecular liquid spectra affected by resonance dipole-dipole
interaction. Chem. Phys. 364 (2009) 69-75.
14. S.F. Bureiko, S.Yu. Kucherov, V.M. Schreiber Molecular
interactions and structure of H- bonded complexes of
bifunctional nitrogen-containing molecules. Polish J.Chem.
83 (2009) 771-785.
64
15. P.M. Tolstoy,
B. Koeppe, G.S. Denisov, H.-H. Limbach
Combined NMR and UV/Vis Spectroscopy in the Solution
State: Study of the Geometries of Strong OHO Hydrogen
Bonds of Phenols with Carboxylic Acids. Angew. Chem. Int.
Ed., 48 (2009) 5745-5747.
16. X. Chen, T.B. Settersten, A.P. Kouzov State- and time-resolved
rotational relaxation signatures in two-color resonant fourwave mixing spectra. J. Raman Spectrosc. 40 (2009) 847-852.
17. A.V. Domanskaya, M.O. Bulanin, K. Kerl, C. Maul Pressure
broadening and shifting Parameters for the spectral lines in
the first overtone vibration-rotation bands of HBr and HI in
mixtures with rare gases. J. Mol. Spectrosc., 253 (1) (2009) 2024.
18. I.K. Tokhadze, T.D. Kolomiitsova, D.N. Shchepkin, K.G.
Tokhadze Z. Mielke Influence of resonance interactions and
matrix environment on the spectra of SF6 dimers in low
tempera- ture nitrogen matrixes. Theory and experiment. J.
Phys. Chem. A, 113 (2009) 6334-6341.
19. S.F. Bureiko, S.Yu. Kucherov Structure and intermolecular
interactions in complexes with hydrogen bond of a series of
bifunctional nitrogen-containing compounds. J, Struct.
Chem. 50 (2009) 712-721.
20. K.S. Rutkowski, S.M. Melikova, J. Janski, A. Koll
Cryospectroscopic and ab initio anharmonic studies of
acetylene-trimethylamine H-bonded complex. Chem. Phys.
375 (2010) 92-100.
21. I.A. Verzhbitskiy, M. Chrysos, F. Rachet, A.P. Kouzov Evidence
for double incoherent Raman scattering in binary gas
mixtures: SF6-N2. Phys. Rev. A 81 (2010) 012702-7.
65
22. P.M. Tolstoy, J. Guo, B. Koeppe, N.S. Golubev, G.S. Denisov,
S.N. Smirnov, H.-H. Limbach Geometries and Tautomerism of
OHN Hydrogen Bonds in Aprotic Solution Probed by H/D
Isotope Effects on 13C NMR Chemical Shifts. J.Phys.Chem.A,
114(40) (2010) 10775 – 10782.
23. O.S. Gulidova, R.E. Asfin, I.M. Grigoriev, N.N. Filippov Air
pressure broadening and shifting of high-J lines of (00011)
← (00001) band of 12C16O2. J. Quant. Spectrosc. Radiat. Trans.
111 (2010) 2315-2320.
24. S.F.Bureiko, S.Yu. Kucherov, IR spectra of cyclic hydrogen-
bonded complexes of bifunctional nitrogen compounds in
solution. Optics and Spectroscopy, 109 (2010) 1117-1126.
25. F.R. Spiering, M.B. Kiseleva, N.N. Filippov, H. Naus, B. van
Lieshout, C. Weijersborg, W.J. van der Zande Line mixing and
collision induced absorption in the oxygen A-band using
cavity ring-down spectroscopy. J. Chem. Phys. 133 (2010)
114305-9.
Scientific Cooperation with:
Paris University (France),
Wroclaw University (Poland),
Free University of Berlin (Germany)
University of Antverp (Belgium)
Technical University of Braunschweig (Germany)
Université d’Angers (France)
Paul Scherrer Institute (Switzerland)
Universite de Franche-Comte, Besancon (France)
66
The unique Bruker IFS-125 HR vacuum Fourier spectrometers
with spectral resolution about 0.01–0.003 cm–1 with set of
special cells for:Gas phase - (L = 10 cm – 100 m), (P = 1 torr –
100 atm), (T = 600 K – 80 K), Cryogenic solutions – (L = 1 mm –
1 m)
Selected projects
Vibronic nature of hydrogen bonding effects in NMR spectra
Ass. Prof. D.N.Shchepkin, Grant RFBR 05-03-33235, 2005-2007
Rotation-vibration relaxation matrix reconstruction using ab
initio calculation and line shape studies. Prof. N. N. Filippov,
Grant RFBR 05-03-32227, 2005-2007.
Analysis of strong anharmonicity of molecular complexes
based on their vibrational spectra: experiment and theory
Prof. K.G. Tokhadze, Grant RFBR 06-03-32073, 2006-2008
Spectroscopy of systems with intermolecular interactions
Prof. K.G.Tokhadze, 2005-2009
High resolution spectroscopy of atmospheric gases. Prof .
N.N. Filippov, 2008-2009
Vibration averaging effects in NMR spectra of hydrogen
bonded complexes Ass. Prof. D.N. Shchepkin, Grant RFBR 0803-00615, 2008-2010
Spectroscopy of molecular complexes. Structure, dynamics
and energy of intermolecular interactions in these systems.
Prof. S.F. Bureiko, Program “The Development of High School
Scientific Potential” of the Ministry of Education and Science of
Russian Federation, 2.1.1/640, 2009-2010
Manifestation of strong anharmonicity in the spectra of
molecular complexes. From ultrastrong hydrogen bond to
van der Waals dimers Prof. K.G.Tokhadze, Grant RFBR 09-0300232, 2009-2011
67
Probing the geometries of functional hydrogen bonds in
solution by combined NMR/UV/Vis spectroscopy Ass. Prof. I.
G. Shenderovich, Grant RFBR 09-03-91336, 2009-2011
Collisional effects on the spectra of molecular gases. Prof.
N.N. Filippov, 2010-2012
Spectroscopy of molecular complexes and clusters: the
shape of absorption bands, structure and dynamics Prof.
K.G.Tokhadze, 2010-2014
68
Nuclear Physics
Prof. Konstantin A. Gridnev, Head of the Department
M. Sc. 1960, Ph. Dr. 1968, D. Sc. 1983.
Professors:
Dr. V.A. Andrianov,
Dr. V.E. Bunakov,
Dr. V.M. Mikhajlov,
Dr. E.P. Grigoriev,
Dr. L.V. Krasnov,
Dr. Yu.N. Novikov, Dr. V.A. Rubchenya
Ass.
Professors:
Dr. L.I. Vinogradov,
Dr. A.K. Vlasnikov,
Dr. V.P. Kondratiev,
Dr.
O.E.
Kraft,
Dr. R.B. Panin,
Dr. V.O. Sergeev,
Dr. V.A. Sergienko,
Dr. S.Yu. Torilov,
Dr. S.N. Fadeev, Dr. V.I. Tselyaev
Heads of laboratories: Dr. S.E. Belov, Dr. V.I. Zherebchevsky
Senior
Researchers:
Dr. F.F. Valiev,
Dr. O.V. Chubinskij,
Dr. A.P. Dubenskij, Dr. N.A. Lyutorovich,
69
Physics
The field of research in the framework of the master program:
"Experimental and theoretical investigations of properties of
atomic nuclei by means of nuclear spectroscopy and nuclear
reactions"
Lectures on a speciality
Nuclear Physics
Actual Problems of Nuclear Physics
Neutron Physics
Structure of atomic nuclei
Theory of atomic nucleus
Quantum Chromodynamics
Exotic Nuclei
Heavy Ion Reactions
Alpha-, beta-, and gamma processes
Cluster Radioactivity and Nuclear Fission
Gamma Rays Resonance Scattering
Introduction to Speciality
Interaction of Radiation with Matter
Basic properties of the atomic nuclei
(nuclear forces)
Introduction to Quantum Electrodynamics
Weak and Electromagnetic Interactions
Radiation Detectors and Nuclear Electronics
Bases of Symmetry Theory
Experimental Methods in Nuclear Physics
Nuclear Reactions Theory
Direct nuclear reactions
70
Gridnev K.A.
Gridnev K.A.
Krasnov L.V.
Mikhajlov V.M.
Mikhajlov V.M.
Andrianov V.A.
Novikov Yu.N.
Bunakov V.E.
Grigoriev E.P.
Rubchenya V.A.
Sergienko V.A.
Sergienko V.A.
Vlasnikov A.K.
Vlasnikov A.K.
Panin R.B.
Panin R.B.
Vinogradov L.I.
Kondratiev V.P.
Sergeev V.O.
Fadeev S.N.
Tselyaev V.I.
Research topics
Investigation of properties of nuclei and of nuclear reactions
mechanisms in a wide range of energies
Modeling the decay of nuclear systems produced in the
heavy ions reactions
Investigation of collective phenomena from femto to nano
levels of structure of matter
Fundamental and applied innovation research of nucleon
systems produced in nuclear reactions in a wide range of
masses and energies
Integrated study of exotic and cluster nuclei
.
Scientific Cooperation with
GSI (Darmstadt, Germany)
University of Jyväskylä (Finland)
Forschungszentrum Juelich (Germany)
Johann Wolfgang Goethe University ( Frankfurt am Main,
Germany)
Special equipment
Beta-spectrometer of π 2 type with equilibrium orbit r=500 mm
and
resolution of 0.1%.
-ray spectrometer with semiconductor detectors of 40-100 cm3
sensitive
volume with resolution 3-4 keV at Eγ = 1.3 MeV.
Position-sensitive detector with microchannel plates.
Equipment for investigation of detectors.
Semiconductor γ- spectrometer for ecological investigations.
Educational laboratory with equipment for nuclear physics
investigations .
U-120 cyclotrone.
71
Selected papers
1. Gridnev, K.A., D'yachenko, A.T., Baryshnikov, V.N., “Pion
production by protons on nuclei near the threshold”, Bulletin
of the Russian Academy of Sciences: Physics 74 (4), 471
(2010)
2. Gridnev, K.A., Rodionova, E.E., “The role of exchange
interaction in elastic scattering of 16O + 16O and 16O + 12C”
Physics of Particles and Nuclei Letters 5 (4), 349 (2008)
3. Gridnev, K.A., Rodionova, E.E., Fadeev, S.N., “Description of
elastic scattering in the 16O + 16O and 16O + 12C systems”
Physics of Atomic Nuclei 71 (7), 1262 (2008)
4. Torilov, S.Yu., Gridnev, K.A., Greiner, W., “New insight on the
chain states and bose-einstein condensate in light nuclei”
International Journal of Modern Physics E 17 (10), 2150
(2008)
5. Gridnev, K.A., Fadeev, S.N., “Applicability of the α-particle
folding model to the description of scattering of α-cluster
nuclei” Bulletin of the Russian Academy of Sciences: Physics
71 (6), 789 (2007)
6. Gridnev, K.A., Torilov, S.Yu., Kartavenko, V.G., Greiner, W.,
“Model of binding alpha-particles and structure of the light
nuclei ” International Journal of Modern Physics E 16 (4),
1059-1063 (2007)
7. Gridnev, K.A., Torilov, S.Yu., “Ikeda diagram within the model
of binding alpha particles” Physics of Atomic Nuclei 69 (7),
1204 (2006)
8. Gridnev, K.A., Gridnev, D.K., Kartavenko, V.G., Mitroshin,
V.E., Tarasov, V.N., Tarasov, D.V., Greiner, W., “On stability
of the neutron-rich oxygen isotopes” International Journal of
Modern Physics E 15 (3), 673 (2006)
9. Kuzmenko N.K., Mikhajlov V.M. The Canonical Heat Capacity
of Normal Mesoscopic Fermion Systems: The Temperature
Evolution and Particle Number Oscillations,
“Statistical Mechanics Research”, Nova Science, New York.
2008. P.181-216.
72
10. Tarasov V.N., Tarasov D.V., Gridnev K.A., Gridnev D.K.,
Kartavenko V.G., Greiner W. Properties of Fe, Ni and Zn
isotopes near the drip-lines.
Int. J. Mod. Phys. E. 2008. V.17. P.1273.
11. Tselyaev V.I. Quasiparticle time blocking approximation
within the framework of generalized Green function formalism
Phys. Rev. C. 2007. V.75. N.2. 024306.
12. Litvinova E.V., Tselyaev V.I. Quasiparticle time blocking
approximation in coordinate space as a model for the
damping of the giant dipole resonance. Phys. Rev. C. 2007.
V.75. N.5. 054318.
13. Litvinova E., Ring P., Tselyaev V. Particle-vibration coupling
within covariant density functional theory.
Phys. Rev. C. 2007. V.75. N.6. 064308.
14. Litvinova E., Ring P., Tselyaev V. Relativistic quasiparticle
time blocking approximation: Dipole response of open-shell
nuclei.
Phys. Rev. C, 2008, V.78, N.1, 014312.
15. Tselyaev V., Speth J., Krewald S. Description of the giant
monopole resonance in the even-A 112-124Sn isotopes
within a microscopic model including quasiparticle-phonon
coupling.
Phys. Rev. C. 2009. V.79. N.3. 034309.
16. Kuzmenko N.K., Mikhajlov V.M. Polynomial method for
canonical calculations.
Physica. A. 2007. V.373. P.283.
17. Kuzmenko N.K., Mikhajlov V.M.
Low Temperature
Resonances in Electron Heat Capacity of Finite System.
Physica. A. 2010. V.389. P.2376.
18. Vlasnikov A.K., Kuzmenko N.K., Mikhajlov V.M., Smirnov
A.S. Investigation of weak pairing correlations in Al
nanograins.
Izv. RAN. Ser. Fiz.. 2010. V. 74. №4. P.611.
73
Selected projects
1. Modeling the process of decay of nuclear systems
produced in heavy ions reactions. Prof. K.A.Gridnev.
RFBR grant 09-02-00141-a, 2009-2010.
2. Organization and holding of the 60-th International
conference on nuclear physics “Nucleus 2010”. Prof.
K.A.Gridnev. RFBR grant 10-02-06040, 2010.
3. Participation in 13-th international conference on nuclear
physics. Prof. K.A.Gridnev. RFBR grant 11-02-08011, 2011.
4. Investigation of pairing and qusipaticle-phonon effects in
nano- and femto-systems. Prof. V.M. Mikhajlov. Program
“Development of scientific potential of higher school”, project
2.1.1/4779. 2009-2010.
5. Theoretical investigations of properties of unstable
nuclei. Dr. V.I. Tselyaev. RFBR grant 05-02-04005ННИО.2005-2008.
74
Optics
Professor N. A. Timofeev, Head of the Department
M.Sc. 1975, PhD 1979, D.Sc. 2000
Laboratory of Laser Spectroscopy and Plasma Spectroscopy
Prof. Yu. A. Tolmachev, Head of the Laboratory
Academic and Research staff: Prof. V.S.Egorov;
A.N.Klyucharev; Associate Prof. A.A.Pastor; Associate
A.A.Kudryavtsev, Principal Res. N.N.Bezuglov; Sen.
Yu.A.Piotrovsky; Sen. Res. I.A.Chehonin; Sen. Res.
Serdobintsev; Res. E.A.Bogdanov; Res. M.A.Chehonin;
O.V.Zhigalov; Head of Student Experimental Lab. M.V.Arhipov
Prof.
Prof.
Res.
P.Yu.
Res.
75
Laboratory of Radiational and Collisional Processes
Prof. Yu. Z. Ionih, Head of the Laboratory
Academic and Research staff: Prof. A.A.Mityureva; Prof.
V.V.Smirnov; Associate Prof. G.V.Zhuvikin; Associate Prof.
N.A.Kryukov;
Principal
Res.
A.Z.Devdarian;
Sen.
Res.
A.V.Meschanov; Sen. Res. G.M.Grigoryan; Sen.Res. A.L.Zagrebin;
Res. I.Yu.Baranov; IT Specialist N.V.Chernysheva; IT Specialist
D.V.Rusov; IT Specialist S.A.Klemeshev
Laboratory of Holography and Laser Optics
Associate Prof. V. S. Suhomlinov, Head of the Laboratory
Academic and Research staff: Sen. Res. E.G.Sheikin; IT Specialist
L.V.Suhomlinova;
Engineer
T.E.Petunina;
Engineer
N.A.Kolchedantseva
Laboratory of Plasma Physics
Prof. Yu. B. Golubovsky, Head of the Laboratory
Academic and Research staff: Prof. B.P.Lavrov; Perof. V.A.Ivanov;
Associate Prof. Yu.E.Skoblo; Ass. A.Yu.Skoblo; Sen. Res.
V.A.Mayorov; Sen. Res. L.G.Bolshakova; Res. A.S.Melnikov; Res.
F.E.Latyshev; Res. S.A.Astashkevich; Engineer G.V.Sokolova
Laboratory of Spectral Analysis
Prof. V. M. Nemets, Head of the Laboratory
Academic and Research staff: Principal Res. S.V.Oshemkov;
Engineer V.E.Evtiheev; Lab Assistant D.A.Prohorov
76
Master Degree Syllabus: “Physical Optics and Lasers’
“Plasma Physics and Chemistry”.
PhD Programs: Optics, Plasma Physics, Laser Physics
Students of Optics Department are trained in different fields of Optics
and Spectroscopy, Plasma Physics, Laser Physics, Elementary
Processes, Gas discharge Physics, Theory of Atomic and Molecular
Collisions, Plasma Chemistry, Great attention is devoted to
experimental methods, modeling of plasmas and processes and to
computer techniques. Education is closely connected with modern
problems in the fields in question and is supported by cooperation
with profiled Institutions in Russia and abroad such as Institute of
Plasma Science and Technology (Greifswald, Germany), Paul
Sabatier University (Toulouse, Franse), Laboratoire pour l’Utilisation
des Lasers Intenses, Antenne Université Paris 6, (Paris, France),
University of Bary (Bary, Italia), University of Uppsala (Uppsala,
Sweden) etc. Last years offer students new facilities due to the
extra-modern laboratory equipped with femtosecond laser Pulsar 5010 (Amplitude Technology, France), Quantel nanosecond laser
(France), supersonic molecular beam with laser and electron
excitation, mass-spectrometry, electron spectrometry and optical
spectrometry in the region 40-2000 nm, as well as the opportunity to
study processes of surface modification by atomic and molecular
supersonic beam and further study of the results of this modification
under super high vacuum (~10 – 10 Torr).
Basic special courses for students:
1. Physics and chemistry of plasma in molecular gases
2. Introduction to physics of electron-atomic collisions
3. Optical methods for the experimental physics
4. Methods and devices for linear spectroscopy
5. Corpuscular optics
6. Cluster physics and optics
7. Kinetics of excited particles in plasma
8. Gas discharge physics
9. Holography
10. Physical processes in gas lasers and laser spectroscopy
11. Nonlinear optics
77
12. Introduction to spectroscopy of molecular gases
13. Gas lasers and their application. plasma chemistry
14. Laser methods of “cold” atoms control in nanotechnology
15. Plasma aerodynamics
Research topics
Laser Physics and
Spectroscopy
Elementary Processes
Plasma Physics
Laser
Physics of Gas Discharges
Spectral Analysis
Supersonic Plasma Dynemics
Selected papers 2007-2010
1. M. A. Khodorkovskii, A. A. Belyaeva, L. P. Rakcheeva, A. A.
Pastor, P. Yu. Serdobintsev, I. A. Shevkunov , N. A. Timofeev,
R. Hallin, and K. Seigbahn “Multiphoton Mass Spectra of XeKr
Molecules in the Range of Excited Xe*6p[5/2]2, 3” Atoms Optics
and Spectroscopy, 2007, Vol. 102, No. 6, pp. 834–841)
2. E. Artamonova, T. Artamonova, A. Beliaeva, D. Gorbov, M.
Khodorkovskii, A. Melnikov, D. Michael, V. Milenin, S.
Murashov, L. Rakcheeva, N.Timofeev “Low pressure water
vapor discharge as a light source 1. Spectroscopic
characteristics and efficiency”, J. Phys. D: Appl. Phys. 2008 41
155206 (8pp)
3. E Artamonova, T Artamonova, A Beliaeva, M Khodorkovskii, A
Melnikov, D Michael, V Milenin, S Murashov, L Rakcheeva, N
Timofeev and G Zissis “Low pressure water vapour discharge as
a light source: II. Electrical characteristics”, J. Phys. D: Appl.
Phys. 42 (2009) 175204 (9pp)
4. M. Khodorkovskii, D. Mikhael, A. Pastor, N. Timofeev, G. Zissis.
Application of similarity laws as a light source diagnostics // J.
Phys. D: Appl. Phys., 2010, 43, 175205.
5. Yu.B.Golubovskii, R.V.Kozakov, V.O.Nekuchaev, I.E.Sheykin,
A.Yu.Skoblo. Influence of the inaccuracy of the plasma potential
on the shape of the electron distribution function obtained from
the probe characteristic. // Plasma Sources Sci. Technol., 2010,
v.19, No.4, 045019.
78
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
Yu.B.Golubovskii, R.V.Kozakov, V.O.Nekuchaev, A.Yu.Skoblo.
Nonlocal electron kinetics and radiation of a stratified positive
column of discharge in neon. // J. Phys. D: Appl. Phys., 2008,
v.41, No.10, 105205 [9 pages].
Yu.B.Golubovskii, A.Timofeev, S.Gorchakov, D.Loffhagen,
D.Uhrlandt. Population of resonance and metastable atoms in a
cylindrical volume of finite size. // Phys. Rev. E, 2009, v.79,
No.3, 036409 [13 pages].
Yu.B.Golubovskii,
A.Yu.Skoblo,
C.Wilke,
R.V.Kozakov,
V.O.Nekuchaev. Peculiarities of the resonant structure of the
electron distribution function in S-, P- and R-striations. // Plasma
Sources Sci. Technol., 2009, v.18, No.4, 045022 [11 pages].
Yu.B.Golubovskii, R.V.Kozakov, V.O.Nekuchaev, I.E.Sheykin,
A.Yu.Skoblo. Influence of the inaccuracy of the plasma potential
on the shape of the electron distribution function obtained from
the probe characteristic. // Plasma Sources Sci. Technol., 2010,
v.19, No.4, 045019 [11 pages].
Yu.Z.Ionikh, A.V.Meshchanov, F.B.Petrov, et al. Partially
constricted glow discharge in an Argon-Nitrogen mixture.
Plasma Phys.Reports, 2010, v.34, p.867.
N.A.Dyatko, Yu.Z.Ionikh, A.V.Meshchanov, et al. Specific
feature of the current-voltage characteristics of diffuse glow
discharge in Ar:N2 mixtures. Plasma Phys.Reports, 2010, v.36,
p.1040.
N.A.Dyatko, Yu.Z.Ionikh, A.V.Meshchanov, et al. Dark phase
effect in the evolution of the positive column of a glow discharge
in Nitrogen. Plasma Phys.Reports, 2011, v.37, p.505.
Phys.Rev.A, 2008, p.022512.
A.Devdariani, A.K.Belyaev, A.Alekseev, H.-PLieberman,
R.Buenker. Ab initio resolved study of the life-time of weakly
bound He(21S)-Ne molecules. Mol.Phys. 2010, v.108, p.757.
A.A.Mityureva,
V.V.Smirnov,
A.B.Bichkov.
Short-pulse
photoexcitation process in the hydrogen atom. Phys.Rev.A,
2009, v.79, p.013402.
V.V.Smirnov. On the estimation of a path integral by means of
the saddle point method. J.Phys.A: Math. and Theor. 2010, v.43,
p.465303.
79
16. G.Grigorian, A.Cenian. Vibrational to electronic energy transfer
from CO to C2 molecules. Chem.Phys.Lett. 2009, v.469, p.247.
17. G.M.Grigorian,
I.V.Kochetov,
A.K.Kurnosov.
Vibrational
distribution of CO molecules in a DC discharge in the presence
of molecular oxygen admixture. J.Phys.D: Appl.Phys. 2010,
v.43, p.085201.
18. V. Sukhomlinov, N.Gerasimov, V.Sheverev. «Propagation of
sound in glow discharge рlasma», J. Phys. D: Appl. Phys. V. 40,
p.p. 2507–2512, 2007.
19. V.S. Sukhomlinov, N. Gerasimov, and V.A. Sheverev,
«Acoustic wave propagation in uniform glow discharge plasma
at an arbitrary angle between the electric field and wave
vectors», J. Applied Phyics, 104, 043301, 2008.
20. V. Sukhomlinov, N.Gerasimov. Supersonic flow with small
perturbation under external influence. Part 2 – Thin profile. Rus.
J. Tech. Phys., 2010, 80, No. 6, PP. 25 – 31.
21. M.Yu.Zaharov, N.N.Bezuglov, N.M.Lisenkov, A.N.Klyucharev,
I.I.Beterov, F.Fuzo, M.Allegrini. Optimization of reduced
absorptive Doppler line shape in gas dynamics beams // Optics
and Spectroscopy 2010 108 749-754.
22. M.Yu.Zaharov, N.N.Bezuglov, A.N.Klyucharev, A.A.Matveev,
K.Michulis, E.Saks, I.Sidoruk, A.Ekers. Reduced absorptive
Doppler line shape in atomic/molecular beams // Optics and
Spectroscopy 2010 102 894-899.
23. Beterov, D.B.Tretyakov, I.I.Ryabtsev, A.Ekers, N.N.Bezuglov.
Ionization of sodium and rubidium nS, nP and nD Rydberg
atoms by blackbody radiation // Phys.Rev.A, v.75, p.052720
(2007).
24. E.A.Bogdanov,
C.A.DeJoseph
Jr,
V.I.Demidov,
A.A.Kudryavtsev, K.Yu.Serditov. Influence of an additional
ballast volume on a pulsed ICP discharge // Plasma Source
Science and Technology 2007 16 697.
25. V.I.Demidov, A.A.Kudryavtsev, S.M.Popugaev, S.F.Adams,
S.Q.Jiao. Formation time of breakdown modeled for the ignition
of air and n-butane mixtures using effective ionization coefficient
// Applied Physics Lett. 2008 93 241501.
80
Selected projects
Physics and Chemistry of nonequilibrium low temperature
plasma. Russia-France-Germany mutual project. Prof. Yu. B.
Golubovsky (2002-2008).
Study and application of low temperature plasmas in light
sources, biotechnology, ecology and medicine. RussiaGermany mutual project. Prof. Yu. B. Golubovsky (2009-2011).
Investigation of physical processes in plasmas and laser
medium, and radiation-substance interaction: diagnostics,
modeling, informational aspects. 11.0.42.2010. Prof. N. A.
Timofeev (2010-2011).
Development of effective UV light sources on the base of
gas mediums with water molecule nanoparticles in
collaboration with scientific organizations of France.
02.513.12.3084. Prof. N. A. Timofeev (2009-2010).
Development of electron emitters stable to operate in
aggressive medium. 16.513.11.3041. Prof. N.A.Timofeev.
Study of gas discharge plasma created in a supersonic
molecular beam. NK-387P. Prof. N. A. Timofeev (2009-2010).
Contract
with
ООО
«KIRISHINEFTEORGSINTEZ»
«Development of methodic and equipment to define hard
paraffines in oil», 2007, Prof. V. M. Nemets.
Contract
with
ООО
«KIRISHINEFTEORGSINTEZ»
«Modification of chromatographer to study the contest of
izo- and n-paraffines», 2008,. Prof. V. M. Nemets.
Contract with ООО «KIRISHINEFTEORGSINTEZ» «Study of
informational aspects of optical spectra of oil fractions»,
2011, Prof. V. M. Nemets.
Contract with NPO «KOREKS» «Investigation of formation
conditions and characteristics of optical non-homogeneity
in laser breakdown of transparent dielectrics», 2007, Prof. V.
M. Nemets.
81
82
Grant RFBR 05-03-33252 «Theoretical and experimental
study of the influence of non-adiabatic transfer of valent
electrons on the ionization of Rydbergh atom-molecular
complexes in dynamic-chaos regime» (2005-2007), Prof.
A.N.Klyucharev.
EU FP6 Marie Curie Transfer of Knowledge Project LAMOL,
Laser manipulation of stochastic molecular processes,
Contract MTKD-CT-2004-014228 (2005-2009).
Grant RFBR No 06-02-17317 (2006-2008) “New effects in
space excitation rate distribution and radiation in spacelimited plasmas of medium and high pressure”. Associate
Prof. A. A. Kudryavtsev.
Grant RFBR No 09-02-01194 (2009-2011) “Cathode region
structure of glow discharge in molecular gases”. Associate
Prof. A. A. Kudryavtsev.
Grant RFBR No 06-02-91225 (2009-2010) “Self-regulation of
high pressure gas discharges and search of their stable
operation”. Associate Prof. A. A. Kudryavtsev.
Photonics
Professor Dr.S. Yuri V.Chizhov, Head of the Department
M.Sc. 1969, Ph.D. 1973 , D.Sc. 2009
Research staff:
Prof. Dr. M.E.Akopyan, Prof. Dr. V.S.Ivanov, Prof. Dr. G.N.Lialin,
Prof. Dr. A.A.Lisachenko, Prof. Dr. A.M.Pravilov, Prof. Dr.
V.K.Ryabchuk, Prof. Dr. V.Sovkov, Prof. Dr. A.A. Tsyganenko,
D.Sci. V.S.Zapasky,
Assoc.Prof. Dr. S.V.Litke, Assoc.Prof. Dr. N.M.Tsyganenko, Dr.
V.A.Alexeev, Dr. L.L.Basov, Dr. A.Golovin, Dr. V.G.Davydov, Dr.
Yu.K.Dolgikh, Dr. Y.Efimov, Dr. V.I.Kleimenov, Dr. G.G. Kozlov, Dr.
V.N.Kuznetzov, Dr. V.V.Ovsyankin, Dr. V.V. Petrov, Dr.
S.V.Poltavtsev, Dr. O.Yu. Podkopaeva, Dr. S.A.Poretsky, Dr.
A.V.Rudakova, Dr. L.G.Smirnova, Dr. G.S. Zhdanov, V.A.Lovzus,
M.Sc.
83
Research topics
Molecular photophysics, molecular spectroscopy, photoprocesses
in small molecules.
Luminescence spectroscopy of solids
Molecular Beam Epitaxy
Photoactivation Spectroscopy of Surface
Steady-state and time-resolved UV and VIS spectroscopy
Photostimulated adsorption and heterogeneous photocatalysis in
gas/solid systems
Photophysics and photochemistry of organic molecules including
biological and dye molecules in solution and adsorbed state.
Infrared spectroscopy of adsorbed molecules and surface
phenomena.
High level quantum chemical calculation of semiconductor
nanoclusters
Special equipment
High Technology Molecular Beam Epitaxy Complex EP1302
High performance state-of-the-art ultra-fast laser systems for
femtosecond spectroscopy
Laser OODR luminescence spectrometer
VUV spectrometer, Laser fluorescence spectrophotometer
NICOLET 510 and NICOLET 5ZDX Fourier-Transform IR
spectrometers
UV-VIS spectrometer UV-2501PC (SHIMADZU) for solution
and adsorption studies
Spectrofluorophotometer 5301PC (SHIMADZU).
Dye Laser system VSL-337NDS (Spectra Physics).
Spectrometer for vacuum ultraviolet spectral region.
Spectrometer SPECORD UV VIS.
UV-VIS spectrometer SpecordM40 for adsorption studies
KSVU-12 spectral luminescence Instrument compatible with
vacuum set up for mass-spectrometric studies of heterogeneous
photo stimulated reactions
Cells for spectral studies at liquid nitrogen and helium
temperatures.
Microspectrofluorimeter MLT-1
84
Selected papers
1. Besser B., Sovkov V. B., Bai J., Ahmed E. H., Tsai C. C., Xie
F., Li Li, Ivanov V. S., Lyyra A. M. Experimental
investigation of the 85Rb2 a3 u+ triplet ground state:
Multiparameter Morse long range potential analysis. J.
Chem. Phys., 131(2009)094505.
2. Xie F., Minaev K. V., Sovkov V. B., Ivanov V. S., Li D., Li Li.
The Hyperfine Structure Analysis of the K2 23 g+ State.
Chem. Phys. Lett., 493(2010)238.
3. Emeline, A.V., Ryabchuk, V.K., Serpone, N. Dogmas and
Misconceptions in Heterogeneous Photocatalysis. Some
Enlightened Reflections. J. Phys. Chem. B, 2005, 109,
18515 - 18521.
4. Emeline, A.V., Zhang, X., Jin, M., Murakami, T., Fujishima,
A., Application of the “black body like” reactor for the
measurements of the quantum yield of photochemical
reactions in heterogeneous systems., J. Phys. Chem. B,
2006, 110, 7409 – 7413
5. Emeline, A.V., Sheremetyeva, N.V., Khomchenko, N.V.,
Ryabchuk, V.K., and Serpone, N., Photoinduced formation
of defects and nitrogen-stabilization of color centers in
N-doped titanium dioxide, J.Phys.Chem. C, 2007, 111,
11456 - 11462.
6. Serpone, N., Emeline, A.V., Kuznetsov, V.N., Ryabchuk,
V.K., Visible-Light-Active Titania Photocatalysts. The
case of N-doped TiO2s – properties and some
fundamental issues, Inter. J. Photoenergy, 2008, 1, 1 – 19.
7. A.V. Emeline, N.V. Sheremetyeva, N.V. Khomchenko, G.N.
Kuzmin, V.K. Ryabchuk, W.Y. Teoh, and R. Amal,
Spectroscopic Studies of Pristine and Fluorinated NanoZrO2 in Photostimulated Heterogeneous Processes, J.
Phys. Chem. C, 2009,113, N 11, 4566 – 4583.
85
8. A.A. Lisachenko, A.O. Klimovskii, R.V. Mikhailov, B.N.
Shelimov and M. Che. Low-pressure chemical and
photochemical reactions of oxides of nitrogen on
alumina taken as a model substance for mineral dust in
relation to air pollution// Catalysis Today, Volume 119,
Issues 1-4, 15 January 2007, Pages 247-251
9. Andrei A. Lisachenko, Ruslan V. Mikhailov, Lev L. Basov,
Boris N. Shelimov, Michel Che. Photocatalytic Reduction
of NO by CO on Titanium Dioxide Under Visible Light
Irradiation. //Journal of Physical Chemistry C. 2007, V.111,
P.14440-14447
10. A.A. Lisachenko. Electron and molecular processes on
the surface of wide-bandgap oxides induced by
photoexcitation of point defects. Physica B: Condensed
Matter, Volume 404, Issues 23-24, 2009, Pages 4842-4845
11. Ruslan V. Mikhaylov, Andrei A. Lisachenko, Boris N.
Shelimov, Vladimir B. Kazansky, Gianmario Martra, Gabriele
Alberto and Salvatore Coluccia. FTIR and TPD Analysis of
Surface Species on a TiO2 Photocatalyst Exposed to
NO, CO, and NO−CO Mixtures: Effect of UV−Vis Light
Irradiation. J. Phys. Chem. C, Vol.113, No 47, 2009,
20381-20387.
12. N. Serpone, A.V. Emeline, V.N. Kuznetsov, V.K. Rybchuk.
Second Generation Visible-Light-Active Photocatalysts:
Preparation, Optical Properties and Consequences of
Dopants in the Band Gap Energies of TiO2 ,
in:“Environmentally Benign Catalysts: Applications of
Titanium Oxide-Based Photocatalysts”; Anpo, M., Kamat,
P.V., Eds.; Springer: New York, 2010, P. 35 – 113.
13. V.N. Kuznetsov, N. Serpone. On the origin of the spectral
bands in the visible absorption spectra of visible-lightactive TiO2 specimens. Analysis and assignments. J. Phys.
Chem. C. 2009. V. 113, N. 34, P. 15110 – 15123.
14. V.N. Kuznetsov, N. Serpone. Visible light absorption by
various titanium dioxide specimens. J. Phys. Chem. B. 2006.
V. 110. N 50. P. 25203 – 25209.
86
Selected projects
Photochemical reactions on the surface of solid
oxide catalysts in relation to air pollution and
purification problems. Prof. A.A. Lisachenko, Grant
INTAS 03-51-6088, 2004-2006.
Heterogeneous Chemistry and Atmospheric Ice Prof.
A.A.Tsyganenko, Grant INTAS, 2004-2006.
Triplet States of Alkali Diatomic Molecules: Potential
Functions, Deperturbation, and Hyperfine Analysis.
Dr. V.B.Sovkov. Grant NSFC-RFBR-10-03-91151, 20102011.
Observation and analysis of electronic states of K2,
Rb2, and Cs2 . Dr. V.B.Sovkov. Grant NSFC-RFBR-0503-39012, 2005-2007
Triplet States of Alkali Diatomic Molecules: Potential
Functions, Deperturbation, and Hyperfine Analysis.
Dr. V.B.Sovkov. Grant NSFC-RFBR-10-03-91151, 20102011.
Photochemical reactions on the surface of solid
oxide catalysts in relation to air pollution and
purification problems.Prof. A.A. Lisachenko, Grant
INTAS 03-51-6088, 2004-2006.
Atomic Rearrangements on TiO2 Surface under UVirradiation. Prof. A.A. Lisachenko, projects in State
Contracts №40.012.1.1.1152, № 02.434.11.2027, 20022007, Federal Program of MinScience "Investigations and
designs on prioritized directions ".
Development of fundamental principles of spectral
sensitization of TiO2-based photocatalysts, design of
self-sensitized photocatalysts based on surface
nanosized 2D-heterostructures of TiO2-x/TiO2 Prof.
A.A. Lisachenko, Grant RFBR 09-03-00795, 2009-2011.
87
88
Project IUPAC: Braslavsky, S.E., Emeline, A.V., Litter,
M., Palmisano, L., Parmon, V.N., Serpone, N.,
Bahnemann, D., Bolton, J., Braun, A.M., Cassano, A.,
Koopal, L.K., Ryabchuk, V.K., Savinov, E., “Glossary of
terms used in photocatalysis and radiocatalysis”,
IUPAC Recommendations, 2011, J. Pure and Appl.
Chem., in press.
Polymer Physics
Professor Evgeni Rjumtzev, Head of the Department
M.Sc. 1962, Ph.D. 1968, D.Sc. 1975
Research staff:
Professors: Prof. Dr. Andrey V. Lezov, Prof., Dr. Nikolay V.
Tsvetkov, Prof. Dr. Alexander P. Kovshik;
Assoc. Professors.: Dr. Igor P. Kolomiets, Dr. Alexander B.
Mel’nikov, Dr. Sergey. G. Polushin, Dr. Tatiyana A. Rotinyan, Dr.
Nataniya P.Yevlampieva, Dr. Galina E. Polushina;
Ass. Professors: Dr. Vera O. Ivanova, Dr. Alexandr S. Gubarev;
Senior research workers: Dr. Nataliya A. Mikhailova, Dr. Georgi
M. Pavlov.
Research workers: Dr. Mariya E. Mikhailova, Dr. Vyacheslav B.
Rogozhin, Dr. Svetlana A. Kovshik, Dr. Nikita A. Karetnikov,
Alexey Z. Khrustalev, Alexander A. Karetnikov, Irina E.
Matushenko, Nina V. Pimonenko.
Post graduate students: Liliya A. Dobrun, Elena V. Lebedeva,
Nina G. Mikusheva, Alexey A. Lezov, Irina N. Matveeva.
89
Main educational activity:
Physics (Physics of polymers and liquid crystals)
Master program:
Physics of polymers and liquid crystals
Lectures:
Bachelor degree
Introduction to physics of polymers and liquid crystals
Statistical physics of macromolecules
Physics of liquid crystals
Electrical and optical properties of solutions
Application of liquid crystals in science and technology
Physical and chemical properties of colloidal systems
Master degree
Dynamics of polymers
Molecular hydrodynamics and optics of polymers
Physics of polyelectrolytes and biopolymers
Chemistry of polymers and monomers
Physics of supramolecular systems
Interaction of liquid crystals with external fields
New polymer and liquid crystalline functional materials
Polymers in medicine and pharmacology
Research Topics:
Structure, conformation and electrooptical properties of
dendrimers and dendronized polymers;
The self-assembly in polymer systems. Structure and
properties of polyelectrolyte and interpolyelectrolyte
complexes;
Electro- and magnetooptics of polymer and low-molecular
liquid crystals;
Applications of liquid crystals.
90
Special equipment:
Experimental installation for electric and flow birefringence
measurements;
Dielectric spectrometer;
Experimental
installation
for
isothermal
diffusion
measurements;
Analytical ultracentrifuge;
Dynamic light scattering spectrometer.
Books:
1. I.P.Kolomiets, D.Lacey, P.N.Lavrenko in book “Molecular and
Colloid Electrooptics” Ed. By Stoylov S., Stoimenova M, CRC
Taylor & Francis. 2007
2. N.P.Yevlampieva
in
book
“Molecular
and
Colloid
Electrooptics” Ed. By Stoylov S., Stoimenova M, CRC Taylor &
Francis. 2007
3. A.V. Zinchenko, O.A. Pyshkina, A.V. Lezov, V.G. Sergeyev, K.
Yoshikawa. Single DNA molecules: Compaction and
Decompaction. In book “DNA interactions with Polymers and
Surfactants” (ed.by R.S.Dias, B.Lindman). Wiley-Interscience,
New Jersey, 2008.
Special papers.
1. Dadivanyan, A. K., Grishchenko, A. E., Tsvetkov, N. V.,
Ryumtsev, E. I. “Short-Range Orientational Order in
Polymer-Solvent Systems” Polymer Sci. Ser B, Vol: 50,
Issue: 9-10, P: 271-298
2. A.V. Lezov, G.E. Polushina, M.E. Mikhailova, E.I.Rjumtsev.
Self-assembly of Sulfonated Polystyrene Ionomers in
Chloroform. Macromolecular Symposia, 2009. 278. 1. P. 4856.
91
3. N. V. Tsvetkov, S. V. Bushin, M. A. Bezrukova, E. P.
Astapenko, V. O. Ivanova, N. G. Mikusheva, E. V. Lebedeva,
A. N. Podseval’nikova, V. I. Slavyanov, and A. K. Khripunov.
Conformational, Optical, and Electrooptical Properties of
Cellulose Pelargonates in Solutions. Russian Journal of
Applied Chemistry, 2011, Vol. 84, No. 1, pp. 156−163.
4. N. P. Yevlampieva, M. Yu. Gorshkova, I. F. Volkova, E. S.
Grigoryan, A. A. Lezov, A. P. Khurchak, and E. I. Ryumtsev
Molecular Properties of Modified Chitosan Containing a
Quaternary Amino Group. 132 Polymer Science, Ser. A,
2011, Vol. 53, No. 2, pp. 124– 132
5. S. K. Filippov, A.V. Lezov, O.Yu. Sergeeva, A. S. Olifirenko,
S. B. Lesnichin, N. S. Domnina, E.A. Komarova, M.Almgren,
G. Karlsson, P.Štepanek Aggregation of dextran
hydrophobically modified by sterically-hindered phenols
in aqueous solutions: Aggregates vs. single molecules.
European Polymer Journal 44 (2008) 3361–3369
6. B.A. Noskov, A.Yu. Bilibin, A.V. Lezov, G. Loglio, S.K.
Filippov, I.M. Zorin, R. Miller. Dynamic surface elasticity of
polyelectrolyte solutions. Colloids and Surfaces A:
Physicochem. Eng. Aspects 298 (2007) 115–122
7. A.Wild, F. Schlu¨tter, G. M. Pavlov, Ch. Friebe, G. Festag, A.
Winter, M.D. Hager, V. Cimrova´, U.S. Schubert. pConjugated Donor and Donor–Acceptor MetalloPolymers. Macromol. Rapid Commun. 2010, 31, 868–874
8. A.V. Maksimov, G. M. Pavlov
and
I. V. Kusheva.
Orientational Order in Nanolayers of Cast Polymer Films.
Langmuir, 2009, 25 (16), pp 9085–9093
9. D. Scanu, N.P.Yevlampieva, and R. Deschenaux. Polar and
Electrooptical Properties of [60]Fullerene-Containing
Poly(benzyl
ether)
Dendrimers
in
Solution.
Macromolecules, 2007, 40 (4), pp 1133–1139
10. V. T. Lebedev, D. N. Orlova, A. B. Mel’nikov, and
L.V.Vinogradova.
Self_Organization
of
Sulfonated
Polystyrene Ionomers with Various Contents of
Ionogenic Groups in Toluene: Neutron Scattering Study.
Polymer Science, Ser. A, 2009, Vol. 51, No. 9, pp. 965–973.
92
11. Aksenova, E; Karetnikov, A; Kovshik, A; Kryukov, E;
Romanov, V. Light propagation in chiral media with large
pitch. J Optical Sos. Of America. A-Optics Image Sci and
Vis. 25 (3), 2008, P. 600-608
12. E. V. Aksenova, A. A. Karetnikov, A. P. Kovshik, E. V.
Kryukov, and V. P. Romanov. Propagation of Light through
a Forbidden Zone in Chiral Media. Optics and
Spectroscopy, 2008, Vol. 104, No. 6, pp. 909–913
13. S. G. Polushin, V. B. Rogozhin, E. I. Ryumtsev, and A. V.
Lezov. The Kerr Effect in the Vicinity of the Transition
from the Isotropic to Smectic A Phase. Russian Journal of
Physical Chemistry, 2006, Vol. 80, No. 7, pp. 1016–1020
14. Kovshik, A; Magdysyuk, O; Polushin, S; Barmatov, E;
Barmatova, M; Ryumtsev, E . Dielectric Properties of
Liquid-Crystalline Copolymers with Side Cyanobiphenyl
Groups and Acrylic Acid Units. Pol Sci Ser A. 52 (2), 2010,
119-125
15. A.Gubarev, Jan-Michael Y. Carrillo, A.V. Dobrynin.. ScaleDependent Electrostatic Stiffening in Biopolymers.
Macromolecules 2009, 42, 5851–5860
16. Polushin S., Rogozhin V., Beloborodov I., Ryumtsev E.,
Kozlovsky M. Existence of two different isotropic phases
as a reason for bistable phase behavior of an LC sidechain
polymethacrylate.
Macromolecular
Rapid
Communications Vol. 29, Is. 3, 1 2008, P. 224-228.
Selected Projects
1. RFBR grant 06-03-3286. Liquid crystalline branched
polymers and dendrimers. Molecular properties, electrooptics
and melt dynamics.
2. RFBR grant 09-03-00872. Electrooptics of the melts of liquidcrystalline comb-like polymers and metallomesogenes.
Equilibrium and denamic properties.
3. RFBR grant 06-03-12237.Mechanism of Si/fullerene
containing polymers polarization in dependence on chemical
structure macromolecules and position of intramolecular
acceptors.
93
4. RFBR 06-03-32601 Dendritic polymers with various cores:
conformation and physical properties of macromolecules in
dilute solutions.
5. RFBR 09-03-00489 Polymerized micelles: conformation and
physical properties of macromolecules in dilute solutions
6. RFBR 07-03-00459 Structure, dimensions and electrooptical
properties of polyaniline obtained in matrix of polyelectrolytes
7. RFBR 11-03-00739 Molecular properties and self-assembly
of polyampholytes and polyelectrolytes in solutions
94
Quantum Magnetic Phenomena
Professor Vladimir I. Chizhik, Head of the Department
Ph. D. 1966, D. Sc. 1982, Prof. 1986
Research staff:
Dr. Sc. S.V. Dvinskikh, Dr. Sc. T.N. Smekalova, Dr. V.S.
Kasperovich, Dr. A.V. Komolkin, Dr. V.V. Frolov, Dr. V.V. Matveev,
Dr. A.V. Egorov, Dr. S.M. Sukharzhevski, Dr. V.S. Baranov, Dr. N.M.
Vecherukhin, Dr. M.G. Shelyapina, Dr. N.A. Grigorieva, Dr. K.V.
Tyutyukin, Dr. A.V. Donets, M.V. Popova, Yu.S. Tchernyshov, M.S.
Pavlova, K.B. Nerinovski, S.A. Lavrov, A.V. Chudin
95
Three educational programs for Master of Science are realized
at the Department:
1. “Magnetic resonance and its applications”.
2. “Tomography technologies in modern medical diagnostics”.
3. “Quantum radiophysics” (different aspects of applications of
radiospectroscopic methods).
Research topics
nuclear magnetic relaxation of NMR tomography in low
various nuclei in liquids, and
magnetic field;
especially
in
electrolyte NMR in porous media and in
solutions;
heterogeneous
systems,
NMR in low magnetic fields and
particularly, in micellar systems;
in the Earth magnetic field;
ESR and NMR in biological
liquid crystals (NMR spectra
objects;
and relaxation);
practical applications of NMR,
NMR in solids, particularly, in
ESR and NQR;
magnetics
and computer simulations (quantum
nanocomposites;
chemistry
and
molecular
ESR in high and low magnetic
dynamics) in solids, liquids,
field;
liquid crystals and solutions.
ESR
in
mineralogy
and
ecology;
The main direction of the relaxation investigations is the study of
peculiarities of NMR relaxation and microstructure in electrolyte
solutions which are very interesting objects due to their important
role in various physical, chemical, biological, and technological
processes.
The study of the NMR in geomagnetic field was started in 1956 when
the first nuclear induction signals had been registered at the
laboratory in the country. The Department has some priority results
in this area. Experiments in the NMR imaging (MRI) in very low
magnetic fields were started in 1979.
The investigation of the NMR in liquid crystals have been carried out
since 1970. Molecular dynamics simulation of liquid crystals was
96
used for the investigation of conformational structure and mobility of
liquid crystals and for calculation of NMR spectra. The study of
NMR-relaxation and diffusion processes in liquid crystals is another
line of the investigations.
The equipment for detection of the ESR in very low magnetic fields
has been created and a number of the investigations of free
radicals as spin-labels have been carried out. The method of the
separation of contributions to the total ESR line shifts due to the
spin-exchange process and superfine interaction was developed
using the nonlinear dependence of the electron energy levels on
magnetic field.
The Department participates in the scientific and educational
collaboration with universities from many countries (Germany,
Sweden, Finland, France, Poland, Japan, Denmark, Ukraine, Spain,
a.o.)
Conferences
1. The Department organizes two annual conferences and
schools:
2. International Symposium and Summer School “Nuclear
Magnetic Resonance in Condensed Matter” (since 2004).
3. “School “Spinus”” – “Magnetic Resonance and its
Applications” (since 2004) (School-conference of the SaintPetersburg State University for young scientists).
Selected books and papers
1. “Quantum Radiophysics. Magnetic Resonance and its
Applications”. SPb, 2009. 706 pp. Ed. by V.I. Chizhik (in
Russian).
2. S.V. Dvinskikh, V.I. Chizhik. Cross-Polarization with Radiofrequency Field Phase and Amplitude Modulation under
Magic-Angle Spinning Conditions. Journal of Experimental
and Theoretical Physics. 2006. Т. 102. № 1. С. 91-101.
97
3. N. A. Mel’nichenko, V. I. Chizhik, A. S. Vyskrebentsev, and A.
V. Tyuveev.The Temperature Dependences and Methods
for the Functional Representation of the Rates of Proton
Magnetic Relaxation in Aqueous Solutions of
Electrolytes. Russian Journal of Physical Chemistry A,
2009, Vol. 83, No. 8, pp. 1307–1314
4. V.I. Chizhik, V.S. Kasperovich, M.G. Shelyapina, Yu. S.
Chernyshev. Exchange model for proton relaxation in
disordered metallic hydrides. International Journal of
Hydrogen Energy 36 (2011) 1601-1605.
5. M. Shelyapina, D. Fruchart and P. Wolfers. Electronic
structure and stability of new FCC magnesium hydrides
Mg7MH16 and Mg6MH16 (M = Ti, V, Nb): an ab initio study.
Int. J. Hydrogen Energy 35 (2010) 2025-2032
6. M.Yu. Siretskiy, M.G. Shelyapina, D. Fruchart, S. Miraglia,
N.E. Skryabina. Influence of a transition metal atom on
the geometry and electronic structure of Mg and Mg–H
clusters. Journal of Alloys and Compounds, 480 (2009) 114116.
7. S. Miraglia, D. Fruchart, N. Skryabina, M. Shelyapina, B.
Ouladiaf, E.K. Hlil, P. de Rango, J. Charbonnier. Hydrogeninduced structural transformation in TiV0.8Cr1.2 studied
by in situ neutron diffraction. Journal of Alloys and
Compounds 442 (2007) 49-54.
8. S.V. Dvinskikh, K. Yamamoto, A. Ramamoorthy. Separated
local field NMR spectroscopy by windowless isotropic mixing.
Chem. Phys. Lett. 419, 168-173 (2006).
9. S.V. Dvinskikh, D. Sandström, H. Zimmermann, A. Maliniak.
Carbon-13 NMR spectroscopy applied to columnar liquid
crystals. Progr. Nucl. Magn. Reson. Spectrosc. 48, 85-107
(2006).
10. S. V. Dvinskikh, U. Dürr, K. Yamamoto, A. Ramamoorthy. A
high resolution solid state NMR approach for structural
studies of bicelles. J. Am. Chem. Soc. 128, 6326-6327
(2006).
98
11. S. V. Dvinskikh, K. Yamamoto, A. Ramamoorthy.
Heteronuclear isotropic mixing separated local field NMR
spectroscopy. J. Chem. Phys. 125, 034507 (2006).
12. S. V. Dvinskikh, I. Furó. Nuclear magnetic resonance
studies of translational diffusion in thermotropic liquid
crystals. Russ. Chem. Rev. 75, 497-506 (2006).
13. S. V. Dvinskikh, J. Thaning, B. Stevensson, K. Jansson, S.
Kumar, H. Zimmermann, A. Maliniak. Mesomorphism in
Columnar Phases Studied by Solid-State Nuclear
Magnetic Resonance. Phys. Rev. E, 74, 021703 (2006).
14. I.Furó, S. V. Dvinskikh. Field gradient NMR of liquid
crystals. In: Modern Magnetic Resonance, Vol. 1.
Chemistry (G. A. Webb, Ed.), Springer, Dordrecht, 2006. pp.
113-118.
15. S. V. Dvinskikh, K. Yamamoto, U. H. N. Dürr, A.
Ramamoorthy. Sensitivity and Resolution Enhancement
in Solid-State NMR Spectroscopy of Bicelles. J. Magn.
Reson. 184, 228-235 (2007).
16. S. V. Dvinskikh. Separated local field NMR spectroscopy
in columnar liquid crystals. In: Thermotropic Liquid
Crystals: Recent Advances (A. Ramamoorthy, Ed.), Chapter
4, p. 107-130, Springer, 2007.
17. V. Castro, S. V. Dvinskikh, G. Widmalm, D. Sandström, A.
Maliniak. NMR Studies of Membranes Composed of
Glycolipids and Phospholipids, BBA – Biomembranes
1768, 2432-2437 (2007).
18. S.V. Grigor’ev, N.A. Grigor’eva, A.V. Syromyatnikov, K.S.
Napol’skii, A.A. Eliseev, A.V. Lukashin, Yu.D. Tret’yakov, H.
Eckerlebe, “Two-Dimensional Spatially Ordered Al2O3
Systems: Small-Angle Neutron Scattering Investigation”,
JETP Letters, v.85, N9, 2007, p.549-554.
99
19. S. V. Grigoriev, K. S. Napolskii, N. A. Grigoryeva, A. V.
Vasilieva, A. A. Mistonov, D. Yu. Chernyshov, A. V.
Petukhov, D. V. Belov, A. A. Eliseev, A. V. Lukashin, Yu. D.
Tretyakov, A. S. Sinitskii, and H. Eckerlebe, «Structural and
magnetic properties of inverse opal photonic crystals
studied by x-ray diffraction, scanning electron
microscopy, and small-angle neutron scattering»,
Physical Review B, v.79, 045123, 2009.
20. Kirill S. Napolskii, Nina A. Sapoletova, Dmitriy F.
Gorozhankin, Andrey A. Eliseev, Andrei V. Petukhov, Dmytro
V. Byelov, Alexander A. Mistonov, Natalia A. Grigoryeva,
Wim G. Bouwman, Kristina O. Kvashnina, Anatoly A.
Snigirev, Dmitry Yu. Chernyshov, Alexandra V. Vassilieva,
Sergey V. Grigoriev, Fabrication of Artificial Opals by
Electric-Field-Assisted Vertical Deposition, Langmuir,
2010, v. 26(4), pp. 2346-2351
21. S.V. Grigoriev, A.V. Syromyatnikov, A.P. Chumakov, N.A.
Grigoryeva, H. Eckerlebe, K.S. Napolskii, A.A. Eliseev, A.V.
Petukhov, “Nanostructures: scattering beyond the Born
approximation”, Phys.Rev.B, v.81, 125405, 2010.
22. V.V. Matveev, D.A. Baranov, G.Yu. Yurkov, N.G. Akatiev, I.P.
Dotsenko, S.P. Gubin. Cobalt nanoparticles with
preferential hcp structure: A confirmation by X-ray
difraction and NMR. Chem.Phys. Lett., 422, 402 (2006).
23. I.V. Pleshakov, E. Ylinen, P. Paturi, V. V. Matveev, R. Laiho.
Phonon echo in superconducting MgB2. Europhys.
Letters, 2009, 85 (6), p.67001.
24. Denis A. Markelov, Vladimir V. Matveev, Petri Ingman,
Marianna N. Nikolaeva, Erkki Lahderanta, Vladimir A.
Shevelev, and Natalia I. Boiko. NMR Studies of
Carbosilane Dendrimer with Terminal Mesogenic
Groups. J. Phys. Chem. B 2010, 114, 4159.
25. M. V. Popova, Y. S. Tchernyshev, D. Michel.13C NMR study
of the influence of the Aerosil surface charge on the
short-chain surfactant adsorption. Colloid Polym Sci.
2006, 285, p. 359.
100
Selected Projects
1. “Microstructure and molecular mobility in ionic liquids
and concentrated electrolyte solutions as studied by
multinuclear magnetic resonance and computer
simulations (quantum chemistry and molecular
dynamics methods)” Prof. V.I. Chizhik, Grant RFBR 10-0301043-а, 2010-2012
2. “Forming of microstructure of ionic solutions containing
various, including biological, components. Hydrophobic
versus Hydrophilic interactions” Prof. V.I. Chizhik, Grant
RFBR 07-03-00735-а, 2007-2009
3. “Theoretical and experimental investigation of the
micelles and dendrimers in the solution and ternary
systems.
Dr. M.V. Popova, Grant RFBR 08-03-01139,
2008-2009.
4. “Magnetic Resonance Imaging Applications for Chemical
Engineering” Dr. Sc. S.V. Dvinskikh, Grant of Swedish
Research Council, 2009-2011
5. “Microstructure, electronic structure and hydrogen
kinetics in intermetallic nanostructured composites for
hydrogen storage using the NMR data and quantum
chemistry calculations” Prof. V.I. Chizhik, Grant of the
Russian Ministry of Education and Science “Development of
High School Scientific Potential” (Project No 2.1.1/2002),
2009-2010
6. “Novel Efficient Solid Storage for Hydrogen” Dr. M.G.
Shelyapina, The Integrated Project NESSHY, Contract No.:
518271 (SES6), 2006-2010
7. “Intermetallic and nanostructured Mg-rich compounds
with a large mass capacity of reversible hydrogen
storage” Dr. M.G. Shelyapina, Grant RFBR-CNRS 07-0892168-НЦНИ_а, Russia-France (Perm – St Petersburg –
Novosibirsk – Grenoble - Bordeaux)
101
8. “Electronic density distribution and magnetic structure
of transition metal solid solutions” Dr. M.G. Shelyapina,
Grant RFBR 05-02-16731-а, 205-2007
9. “Molecular dynamics of ions and solvent in carbon
nanomaterials: a comparison of computer modelling and
NMR experiment” Dr. A.V. Egorov, Grant RFBR 07-02400548 2007-2009
10. “Mechanisms of adsorption and diffusion of nonaqueous electrolyte solutions in nanostructured carbon
materials” Dr. A.V. Komolkin, Grant RFBR 09-03-01105,
2009 – 2011
11. “Complex investigation of the barrows in culturalhistorical landscape of the Northern Black Sea Coast”
Dr. Sc. T.N. Smekalova, Grant RFBR 08-06-00374, 20082010
12. “Value of artistic heritage, P.N. Schultz in the modern
Studies of the North-West Crimea” Dr. Sc. T.N.
Smekalova, Grant RHSF 69 11-01-00546а, 2011-2013
13. “Magnetic and transport properties of multilayer
structures by polarized neutrons and synchrotron
reflectometry” Dr. N.A. Grigor’eva, Grant RFBR 09-0201231a
14. “Organization and carry out of the conference “Opal-like
structures” Dr. N.A. Grigor’eva, Grant RFBR 10-02-00634g
15. “Structural and magnetic properties of 2D and 3D
spatially ordered nanosystems by neutron and
synchrotron nondestructive methods” Dr. N.A. Grigor’eva,
Grant 2.1.1/4661, Program of the Russian Government
“Development of the scientific potential of the High School”
16. “Research and development of nanocomposite materials
synthesized on the base of solid-state nanoreactors” Dr.
N.A. Grigor’eva, Grant RF Program 02.434.11.2022
102
Radiophysics
Professor N.N.Zernov, Head of the Department, D. Sc.
Teaching Staff: Prof. G.I.Makarov, Dr. Sci., V.V.Novikov, Cand.Sci.,
A.V.Tyukhtin, Dr. Sci., V.A.Pavlov, Dr. Sci., L.V.Yasnov, Dr. Sci.,
Yu.K.Stishkov, Dr. Sci., G.F.Remenets, Dr. Sci., M.A.Bisyarin, Dr.
Sci., Assoc. Prof. V.E.Gherm, Cand.Sci., S.T.Rybachek, Cand.Sci.,
L.N.Lutchenko,
Cand.Sci.,
N.G.Semenova,
Cand.Sci.,
T.Yu.Alekhina, Cand.Sci. M.A.Pavleyno, Cand.Sci., A.A.Bityukov,
Cand.Sci.I.I.Kononov, Cand.Sci.,Assist. Prof. N.Yu.Zaalov, Ph.D.
University of Leicester, UK, et al.
Research Staff:
T.I.Bichutskaya, Cand.Sci., V.A.Egorov, Cand.Sci, V.V.Kirillov, Dr.
Sci., G.N.Krylov, Dr. Sci., A.B.Orlov, Cand.Sci., A.A.Pylaev,
Cand.Sci., O.I.Stolyarov, Cand.Sci., et al.
103
Directions of teaching:
Radiophysics (undergraduate 4-year bachelor course),
Physics (postgraduate 2- year master course “Wave processes and
methods of their investigations”)
Applied Mathematics and Physics (undergraduate 4-year bachelor
and postgraduate 2- year master course “Electrophysics”)
Basic special courses of the undergraduate bachelor’s program
“Radiophysics”:
Fundamentals of radio electronics, Radio electronics laboratory,
Theory of linear systems,
Nonlinear oscillations and waves,
Introduction to the statistical radio physics, Signal theory, Highfrequency electrodynamics,
Fundamentals of solid-state and
physical electronics, Radio physics laboratory, Geometrical optics
in radio physics, Gas dynamics, Antenna theory, Propagation of
electromagnetic waves in plasma, General acoustics
Basic special courses of the postgraduate master’s program
“Wave processes and methods of their investigations”:
Propagation of radio waves, Wave processes theory, Waves in
random media, Nonlinear acoustics,
Plasma electrodynamics,
Advanced laboratory in radio wave propagation, Advanced
laboratory in acoustics. In addition, a lot of elective disciplines are
studied.
Basic special courses of the undergraduate bachelor’s and
postgraduate master’s programs “Electrophysics”:
Introduction to computer science,
Introduction to simulation
technologies, Digital signal and image processing techniques,
Electrodynamics,
Introduction to electrophysics,
High-voltage
laboratory, Physicochemical hydrodynamics, Physical processes in
liquids and gases under effect of a strong electric field,
Fundamentals of plasma physics,
Elementary processes and
ionization phenomena in gases.
Special courses which can be delivered in English:
Radio wave propagation, Plasma electrodynamics, Wave
propagation in plasma, Waves in random media, Geometrical optics
in radiophysics, Localized wave fields.
104
Main Scope of Scientific Investigations
Laboratory for wave propagation in random media
Research is performed into the high frequency wave propagation in
the ionosphere with the electron density fluctuations, including
theory, numerical modeling, and experiment. The fundamental
methods are developed to treat the HF propagation in the stochastic
ionospheric reflection channel of propagation and to deal with the
UHF propagation in the fluctuating transionospheric channel of
propagation. On the basis of the fundamental results the algorithms
are elaborated and the computer codes are created to characterize
the channels of propagation in term of the field statistical moments
and its random series. Particular attention is paid to the most
disturbed conditions of propagation as occurring in the high-latitude
and equatorial ionosphere.
Selected Papers
1. Zaalov N.Y., Warrington E.M., Stocker A.J., (2007), The effect of
geomagnetic activity on the channel scattering functions of
HF signals propagating in the region of the mid-latitude
trough and auroral zone. Radio Science, 42, RS4005, doi:
10.1029/2006RS003611.
2. Stocker A.J., Zaalov N.Y., Warrington E.M., Siddle D.R., (2009),
Observations of HF propagation on a path aligned along the
mid-latitude trough. Advances in Space Research 44, (6), doi:
10.1016/j.asr.2008.09.038.
3. Gherm, V. E., N. N. Zernov, and H. J. Strangeways (2011),
Effects of diffraction by ionospheric electron density
irregularities on the range error in GNSS dual-frequency
positioning and phase decorrelation, Radio Science, 46,
RS3002,doi:10.1029/2010RS004624
4. Zernov, N. N., Gherm V.E., Strangeways H.J.,(2009), On the
effects of scintillation of low-latitude bubbles on
transionospheric paths of propagation, Radio Science, 44,
RS0A14, doi:10.1029/2008RS004074.
105
5. Beniguel Y., Romano V., Alfonsi L., Aquino M., Bourdillon A.,
Cannon P., De Franceschi, Dubey S., Forte B., Gherm V.E.,
Jakowski N., Materassi M., Noack T., Pozoga M., Roger Spalla
P., Strangeways H.J., Wernik A., Wilken V., Zernov N.N., (2009),
Ionospheric scintillation monitoring and modeling, Annals of
Geophysics, Special Issue: Final Report of the COST296 Action
“Mitigation of Ionospheric Effects on Radio Systems”, vol. 52, 3-4
Laboratory for Radio Wave Propagation
Research is devoted to the fundamental aspects of wave generation
and propagation in media characterized with inhomogeneity,
anisotropy, nonlinearity and dispersion. Recent investigations on LF
and VLF wave generation are followed with development of
approaches for increasing the efficacy of LF/VLF antenna radiation
in the vicinity of three-dimensional inhomogeneities of the ambient
space. Analytical methods are elaborated for computation of 10 kHz
– 1 MHz electromagnetic fields in the Earth-ionosphere waveguide,
taking into account specific features of propagation of the
electromagnetic waves within this frequency band in a threedimensionally inhomogeneous anisotropic waveguide. Analytical and
numerical studies of the lower ionosphere, using experimental data
on radio wave propagation, are performed aimed at correction of the
global model of the lower ionosphere at quiet conditions and
modeling of the large-scale ionospheric perturbations.
Selected Papers
1. Bichutskaya T.I., Makarov G.I. Field of an electric dipole
placed on a large curvature hill // Journal of Communications
Technology and Electronics. 2009. Vol. 54, № 8.
2. Bichutskaya T.I., Makarov G.I. The field of linear radiators near
a semi-cylinder // Journal of Communications Technology and
Electronics. 2010. Vol. 55, № 5.
3. Bichutskaya T.I., Makarov G.I. Dipole radiators near a semicylinder // Journal of Communications Technology and
Electronics. 2010. Vol. 55, № 12.
106
4. Kirillov V.V. Representation of the point-source field in a
spherical waveguide via problem solution in a plane
waveguide// Radiophysics and Quantum Electronics. 2009.
Vol.52, №5-6.
5. Bisyarin M.A. Finite-amplitude acoustic pulses in a
waveguide layer with a longitudinal inhomogeneity // Applied
Mechanics and Technical Physics. 2007. Vol.48, № 6.
6. Pavlov V.A. Kinematic model of the long spark streamer //
Applied Mechanics and Technical Physics. 2010. Vol.51, № 6.
7. Orlov A.B., Uvarov A.N. Lower ionosphere model for noun
quiet conditions and sudden ionospheric disturbance
conditions by the data on VLF propagation // Geomagnetism
and Aeronomy. 2011. Vol.51, №1.
Laboratory of Electrodynamics of Non-Stationary and
Microwave Processes
In the last years the main research activities of the laboratory staff
include the following subjects:
- Theory of radiation of moving charged particles and other moving
sources in different complex media including metamaterials, new
methods of particle acceleration (wake field acceleration using
modern dielectric and active materials), new methods of particle
detection and diagnostics of charged particles beams;
- Radiation and scattering of electromagnetic waves in moving
media;
- Electrodynamics of periodic structures and metamaterials;
- Optimization of interaction of electromagnetic radiation with
medium for measurement of material parameters, remote sensing
and biotechnology;
- Theory of complex antenna systems and its applications to medium
monitoring.
107
Selected Papers
1. Doil’nitsina E.G., Tyukhtin A.V. Radiated power of oscillators
traveling in a moving medium // Radiophysics and Quantum
Electronics. 2007. Vol.50, №4.
2. Tyukhtin A., Kanareykin A., Schoessow P.
Wakefields
generated by electron beams passing through a waveguide
loaded with a slightly dispersive active medium // Physical
Review STAB. 2007. Vol.10, p.051302 (1–6).
3. Tyukhtin A.V., Galyamin S.N. Vavilov-Cherenkov radiation in
passive and active media with complex resonant dispersion //
Physical Review E. 2008. Vol.77, p. 066606 (1–8).
4. Tyukhtin A.V. Using anisotropic dispersive materials for highprecision determination of the energy of charged particles //
Technical Physics Letters. 2009. Vol. 35, №3.
5. Galyamin S.N., Tyukhtin A.V., Kanareykin A., Schoessow P.
Reversed Cherenkov-transition radiation by a charge
crossing a left-handed medium boundary // Physical Review
Letters. 2009. Vol.103, p.194802 (1–4).
6. Galyamin S.N., Tyukhtin A.V. Electromagnetic field of a moving
charge in the presence of a left handed medium // Physical
Review B. 2010. Vol.81, p.35134 (1–14).
Laboratory for Radio-Frequency Cosmic Emission
The main activity of the laboratory is related to investigations of the
Solar radiation at radio frequencies. These investigations have been
recently being carried out in collaboration with Special Astrophysical
Observatory of the Russian Academy of Sciences, basing on
observation of the Sun at centimeter wavelengths using the largest
Russian radio-telescope RATAN-600, this enables a detailed
analysis of physical conditions in active areas. Considered as well
are various problems dealt with radio wave generation and
propagation in the hot plasma of the Solar atmosphere.
108
Selected Papers
1. Bogod V.M., Yasnov L.V. On comparison of radioastronomical
measurements of the magnetic field altitudinal structure with
the data on model approximations//Astrophys. Bull. 2009.Vol. 64,
№4
2. Yasnov L.V., Kaltman T.I., Bogod V.M. Features of the polarized
radioemission from active areas on the Sun // Astronomical
Journal. 2010. Vol. 87, №11.
3. Bogod V.M., Yasnov L.V. Polarization of Microwave Radio
Emission of Flare-Producing Solar Active Regions// Solar Phys.
2009. Vol. 255, p. 253.
4. Yasnov L.V., Karlicky M. An Estimation of Spatial Variations of
Magnetic Field and Superthermal Electron Distribution in cmRadio Burst Source // Solar Phys. 2009. Vol. 260, p.363.
5. Yasnov L.V., Karlicky M. Relation between the Spatial
Distribution and Spectral Index of Superthermal Electron
Distribution in Solar cm-Radio Sources// Solar Phys. 2010. Vol.
264, p.93.
Laboratory of Electrophysics
Laboratory staff made an initial priority contribution to the
electrophysics and electrohydrodynamic science by breadth of
coverage and degree of novelty of the research through the original
methods
development
of
experimental
investigation
of
electrohydrodynamic flows, the conductivity of liquid dielectrics and
mechanisms of their electrification. Currently, this line of research is
developed in the sphere of computer simulation methods of
electrohydrodynamic flows and EHD devices. In recent years, along
with the experimental investigations of corona discharge and electric
wind in the air, EHD flows in liquids and streamer processes under
the influence of pulse voltage, the development of computer
simulation methods of the streamer processes in gases at
atmospheric pressure under the influence of lightning pulse are of
great interest in the laboratory. Also a number of applied problems
relating to questions of heat transfer enhancement by the electric
field are researched. Details could be found at the laboratory site:
noc.pmf.ru.
109
Selected Papers
1. Stishkov Yu.K., Samusenko A.V., Subbotskii A.S., Kovalev A.N.
Experimental study of pulsed corona discharge in air //
Technical Physics. 2010. Vol. 55. № 11.
2. Stishkov Yu.K., Samusenko A.V. Computer simulation of
corona discharge in an inert gas // Surface Engineering and
Applied Electrochemistry. 2008. Vol. 44. № 4.
3. Ashikhmin I.A., Stishkov Yu.K. Structural features of EHD flows
in wire-wire symmetric systems of electrodes // Surface
Engineering and Applied Electrochemistry. 2009. Vol. 45. № 6.
4. Stishkov, Y.K., Samusenko, A.V. Electrohydrodynamics of
liquids and gases: Similarities and distinctions // Surface
Engineering and Applied Electrochemistry. 2010. Vol. 46. № 1.
Patents
Stolyarov O.I. et al. Technique of production of complicated-shape
carbon-composite wares and device for its realization. Russian
Federation Patent №2396168, priority : 31 July 2008, published : 10
August 2010, Proprietor : St.Petersburg University.
Stolyarov O.I. et al. The device for registration of -radiation
(versions). Russian Federation Patent № 2370789, priority: 19 May
2008., published: 20 October 2009,
proprietor: St.Petersburg
University.
International Collaboration
Department teaching and research staff took / takes an active part in
international scientific cooperation. The counterparts are as follows:
University of Alaska, Fairbanks, USA;
Swedish Institute of Space Physics at Uppsala, Sweden;
University of Rennes 1, France;
Universities at Leeds, Newcastle and Leicester, UK;
110
Abdus Salam ICTP at Trieste, Italy;
Institute of Applied Physics, Academy of Sciences of Moldova;
Argon National Laboratory, Wisconsin, USA.
Selected Projects
Ministry of Education and Science Project “Actual problems of
electrodynamics and modern theory of radio wave propagation”,
since 2010.
Ministry of Education and Science Project “Electrophysical
processes in liquids and gases under exposure of strong electric
fields”, since 2010.
Federal Research Project “Effective parameters of metamaterials
and properties of moving particles radiation in their presence”,
since 2011.
Ministry of Education and Science Project “Research of the wave
field strong fluctuations in inhomogeneous ionosphere with
statically inhomogeneous fluctuations of electron number density:
theory and applications to the problems of global satellite
navigation (GLONASS)”, 2008-2009.
Ministry of Education and Science Project “Investigation of
electromagnetic radiation of moving sources in the presence of
media with complex characteristics and development of new
methods of SHF diagnostics”, 2008–2009.
Ministry of Education and Science Project “Processes of radiation
and propagation of electromagnetic waves in natural and artificial
media under the presence of inhomogeneity, dispersion or random
component” , 2009-2010.
Ministry of Education and Science Project “University research
and education centre “Geospheres modeling and monitoring” ”.
European Union Project COST296 “Effects of the Upper
Atmosphere on Terrestrial and Earth-Space Communications”,
2005-2009.
111
“Application of the UAF Eulerian Polar Ionospheric Model for
Research tasks of the High-Latitude ionosphere irregularities
investigation by means of the VHF and UHF Radio Signals
Propagation” CRDF GAP Grant RG0-1370-ST-02 (joint project
with the University of Alaska, Fairbanks), May 2004 – August
2007.
Russian Foundation for Basic Research Grant “Magnetic fields of
active areas at coronal altitudes”, 2009 - 2011.
112
Solid State Electronics
Professor Alexander S.Shulakov, Head of the Department
MS 1971, PhD 1974, D.Sc. 1989
Research staff:
Prof. Dr. A.S.Shulakov, Head of Ultra-Soft X-Ray Spectroscopy
Laboratory,
Prof. Dr. A.S.Vinogradov, Prof. Dr. A.A.Pavlychev, Prof.
E.O.Filatova, Dr.Sc. V.A.Fomichev, Dr. A.A.Sokolov, Dr.
E.P.Savinov, Dr. I.I.Lyakhovskaya, Dr. A.G.Lyalin; Prof. Dr.
A.M.Shikin, Head of Physical Electronics Laboratory,
Prof. Dr. V.K.Adamchuk Prof. Dr. G.G.Vladimirov, Doc.Dr.
S.I.Fedoseenko, Dr. S.A.Shakirova, Dr. A.G.Rybkin, Dr.
D.Yu.Usachev; Prof. Dr. P.P.Konorov, Head of Surface and Interface
Physics Laboratory, Prof. Dr. A.M.Yafyasov, Prof. Dr. O.F.Vyvenko,
Prof. Dr. I.E.Gabis, Prof. Dr. A.P.Baraban, Doc.Dr. E.A.Denisov, Dr.
V.B.Bozhevolnov, Dr. V.A.Dmitriev, Dr. A.P.Vojt, Dr.G.G.Kareva;
Prof. Dr. S.A.Komolov, Head of Electronics of Surface Laboratory,
Prof. Dr. O.M.Artamonov, Dr.Sc. E.F.Lazneva, Prof.Dr.A.S.Komolov,
Senior researcher V.D.Kalganov.
113
Main lecture courses
114
Modern problems of electronics of solids.
Physics of semiconductors.
Physics of crystals.
Physics of inner-shell processes in solids.
Physical electronics.
Physical fundamentals of solid state electronics.
X-ray and electron spectroscopes: principles and applications.
Interaction of photons and electrons with matter/
Quantum chemistry of multiatomic systems fundamentals.
Theory of electronic structure of solids.
Physics and chemistry of nanostructures.
Diffraction methods of crystal atomic and magnetic structures
study.
Physics of surface.
Physical foundations of solid nanostructures synthesis
technologies.
Main semiconductor materials and their diagnostics.
Physics of interface processes in semiconductor and insulators.
Physics of defects in semiconductors.
Physics of disordered semiconductors and insulators.
Non equilibrium electronic processes on semiconductor surface.
Quasiparticles and elementary excitations in solids.
Interaction of hydrogen with solids
Research topics
Generation and interaction of the soft X-rays with matter Theoretical and experimental study of generation of X-rays in solids
and interaction of X-rays with multiatomic systems. Study of atomic
and electronic short-order of solid materials and nanostructures on
surfaces and interfaces by means of the soft X-ray spectroscopy
methods
with
application
of
synchrotron
radiation
(emission/fluorescence,
absorption,
photoemission,
specular
reflection, scattering, photoyield).
Physical electronics – Study of electronic and atomic processes,
including nanostructured phase formation on surfaces and interfaces
of solids by means of photoelectron and Auger electron
spectroscopes and scanning probe microscopy. Photoemission and
photoabsorbtion studies of solid materials with using of synchrotron
radiation of the high-resolution Russian-German Beamline at BESSY
II.
Physics of interfaces and low dimension systems - Study of atomic
and electronic properties of semiconductor interfaces by means of
electrophysical methods, thermo- and electro- luninescense, field
effect in electrolyte, hydrogen penetration kinetics.
Low energy electron and laser light interaction with surfaces Study of electronic properties of surfaces, surface nanostructures
and organic-inorganic interfaces – by means of low-energy electron
spectroscopes, e-2e correlation spectroscopy, laser induced mass
spectrometry, photo-voltage and gas-sensing measurements.
115
Selected papers
1. Zimina A., Shulakov A., Eisebit S., Eberhardt W., Depth resolved
soft X-ray emission
spectroscopy of Si-based materials,Surf.Rev.Lett., v.9, n.1, 461-467 (2002).
2. Huebinger F., Shulakov A.S., Starke K., Grigoriev A.,Kaindl G.,
Surface X-ray emission from lanthanide metals,- Surf.Sci., v.256,
n.1-2, L137-142 (2003).
3. Shulakov A.S., Giant resonance of one discovery. Vestnik
SPbGU, s.4, v.2, №11, 120-123 (2003).
4. A.B. Preobrajenski, A.S. Vinogradov, S.A. Krasnikov, S.L.
Molodtsov, C.Laubschat, R. Szargan, Resonant photoemission
in solid nitrates: a direct probe of nuclear motion in the coreexcited NO3- anion,- Chemical Physics Letters 368, 125-131
(2003).
5. A.S. Vinogradov, A.B. Preobrazhenski, S.L. Molodtsov, S.A.
Krasnikov, R. Szargan, A.Knop-Gericke, M. Hävecker. Nitrogen
and oxygen core excitations in solid NaNO2 studied by X-ray
absorption and resonant photoemission, Chemical Physics
249(1999)249.
6. Mistrov D.A., A.De Fanis, M.Kidazima, Pavlychev A.A.,et.al,
Vibrational effects on the shape-resonance energy in K-shell
photoionization spectra of CO,- Phys.Rev.A, 68, n. 022508
(2003).
7. A.G.Lyalin,
S.K.Semenov,
A.Solov’yov,
N.A.Cherepkov,
W.Grainer. Hartree-Fock deformed jellium model for metallic
clasters, J.Phys.B: At.Mol.Opt.Phys, 33 (2000) 3653.
8. Filatova E.O., Lukyanov V.A., Barchevitz R., Andre J.-M., Idir M.,
Stemmler P.H., Optical constants of amorphous SiO2 for photons
in the range of 60-3000 eV,- J.Phys.: Condensed Matter, 11,
3355-3370 (1999).
9. Rader O., Prudnikova G.V., Adamchuk V.K., Gudat W, Shikin
A.M. “ Qantum well states of sp- and d-character in thin Au
overlayers on W(110).” Phys. Rev. B. 65, 075403 (2002).
116
10. D. V. Vyalykh, A. M. Shikin, G. V. Prudnikova, A. Yu. Grigor'ev,
A. G. Starodubov and V. K. Adamchuk. Quantum-Well States
and Resonances in Thin Single-Crystal Layers of Noble Metals
on W(110) Substrates. Physics of Sol. St. (Russia), 44, № 1,
157-164 (2002).
11. A.M. Shikin, S.A. Gorovikov, V.K. Adamchuk, W. Gudat, O.
Rader «Electronic structure of carbon nanostripes.» Phys. Rev.
Lett. V.90, p.256803 (2003).
12. A.M. Shikin, D.V. Vyaikh, E. Wesche, Yu. S. Dedkov, W. Gudat,
V.K. Adamchuk “Quantum-well states in bilayers of Ag and Au on
W(110).” Surf. Sci., 540, L638-L642 (2003).
13. S.I. Fedoseenko, D.V. Vyaikh, I.E. Iossifov, R. Follath, S.A.
Gorovikov, R. Püttner, J.-S. Schmidt, S.A. Molodtsov, V.K.
Adamchuk, W. Gudat, G. Kaindl “Commissioning results and
performance of the high-resolution Russian-German Beamline at
BESSY II” Nucl. Instr. and Meth. in Phys. Res. A 505, 718-728,
(2003).
14. V.B.Bogevolnov, A.M.Yafyasov,P.P.Konorov. Effects of selforganization by solid nano-structures on the CdHgTe-surface
forming. Physical thought of Russia, №1, 2003, p.6-13.
15. V.F.Radanzev, A.M.Yafyasov, I.M.Ivankiv. Rashba’s effect in
inversion and reached lauers of InAs. Physics of Semiconductors
(Russia), 2003, v. 37, №2, p.209-215.
16. E.A.Denisov, A.A.Kurdumov. Hydrogen penetration through thin
coatings,
Physical-Chemistry
Mechanics
of
Materials,
36(2000)65.
17. P.P.Konorov, A.M.Yafyasov. Physics of semiconductor
electrodes surface. Monograph, Saint-Petersburg University
Edition, Saint-Petersburg 2003, p.530.
18. A.A.Istratov and O. F. Vyvenko. Exponential analysis in physical
phenomena, Rev. Sci. Instr., 70(1999)1233.
19. O.M. Artamonov, S.N. Samarin, G. Paolicelli, G. Stefani. The use
of the time–energy dispersion in an electron energy analyzer,J.
Elec.Spect., 131-132 (2003), 105.
117
20. S.N.Samarin, J.Berakdar, O.M.Artamonov, J.Kirschner.
Visualizing spin dependent electron collisions in ferromagnets,
Phys. Rev. Lett. 85(2000) 1746.
21. S.A.Komolov, Y.G.Aliaev. N,N`-DBNTCDI/Cu and N,N`DBNTCDA/NTCDA Interface Formation: TCS Study. Phys.LowDim.Struct. 5/6 (2003) 87-98.
22. A.S.Komolov, P.J.Moller. Photoconductivity and oxygen
adsorption on Cu-phthalocyanine films on cadmium sulphide.
J.Appl.Phys.212-213 (2003) 497-500.
23. V.D.Kalganov, N.V.Mileshkina and P.G.Shlyahtenko, “Field
emission and optical studies of photoelectron transport in the
GaAs crystal” J.Phys. Cond. Matter 15 (2003) 5171.
Selected Projects
118
Regularities of interfaces physical-chemical behaviors
formation under molecular layering growth of heterooxides
on silicon surface. Shulakov A.S., Grant RFBR, 01-03-32771,
2001-2003.
25.Investigation of regularities of oscillator strength
spectral distribution in processes of absorption of X-rays
by II period atoms in multiatomic systems. Vinogradov A.S.,
Grant RFBR 98-02-18177, 1998-2000.
Study of empty electron states in 3d atoms cyanide
complexes by means of X-ray absorption and resonant
photoemission spectroscopies.Vinogradov A.S., Grant RFBR
01-03-32285, 2001-2003.
Destroy of parity and change symmetry in processes of
core shells photoabsorption and photoionization
of
molecules and solids. Pavlychev A.A., Grant RFBR 98-0332715, 1998-2000.
Polarizational bremsstrahlung of atoms, ions and clasters.
Lyalin A.G., Grant RFBR 99-02-18294, 1999-2001.
Quantum-size effects in electron and phonon structure in
quantum wires and stripes on stepped substrates. Shikin
A.M., Grant RFBR – DFG 03-02-04024, 2003-2005.
Study of quantum electronic states in noble metal based
multi-layered structures.Adamchuk V.K. Grant RFBR 01-0217287, 2001-2003.
Electronic behaviors of poymer thin films with attended
bondings and their interfaces. Komolov S.A., Grant RFBR 9903-33427, 1999-2001.
Formation and electronic properties of heterojunctions of
semiconducting oligomers and polymers with inorganic
semiconductors. Komolov S.A., Grant RFBR 02-03-32751,
2002-2004.
Program of the Ministry of Science of Russian Federation
(MSRF): Actual Directions in Condensed Matter Physics.
Direction “Surface Atomic Structures” - 4 projects in 20022006, Adamchuk V.K., Vladimirov G.G., Komolov S.A.,
Mileshkina N.V.
Program MSRF: Fullerenes and Atomic Clusters, Project
“Thin film systems based on C60 monolayers, graphite and
f- and d- metals”. Adamchuk V.K., V.R., 2002-2006.
Optical, X-Ray photoelectron spectroscopy by using
Synchrotron Radiation Adamchuk V.K., Grant of the
program “Science and Education Integration of Russia
2002-2006”.The Ministry of Education of Russian
Federation. Theoretical and experimental study of the
transition bremsstrahlung of electron on the surfaces and
interfaces of solids. A.S.Shulakov, Center of Basic Natural
Sciences grant, E.00-3-120, 2001-2002.
Solid state structures based on the triple combinations of
selenides and tellurides of metals with low-dimensional
electronic gas. Konorov P.P. Program “Universities of Russia”
2002 - 2003
Synthesis and investigation of low-dimension structures
based on carbon materials. Konorov P.P., Program
"Universities of Russia", 1998-2000
119
Carbon nano-clusters with adjustable physical properties
formed by fullerene fragmentation. Adamchuk V.K.
Grant
INTAS 2001-2004 N2136
Experimental and theoretical investigation on high
resolution core level excitation of molecules, clusters and
adsorbates. A.A.Pavlychev, DFG, n. 436 Rus 113/339/0-2(R),
2001-2004
Design and creation of effective detectors of radiation
for devices of ecological monitoring. Mileshkina N.V.
Grant NATO Science for piece. 1999-2001,
120
Solid State Physics
Professor Vadim F. Aguekian, Head of the Department
M.Sc. 1961, Ph.D. 1971, D.Sc. 1981
The chair’ branch in A. F. Ioffe Physical-Technical Institute has been
opened in 1987. The branch is headed by academician A. A. Kaplyanskii.
Research Staff: Prof. Ivan V. Ignatiev, Prof. Acad. Alexander A.
Kaplyanskii, Prof. Sergey V. Karpov, Hon. Prof. Boris V. Novikov,
Prof. Alexander V. Selkin, Prof. Michael B. Smirnov, Prof. Sergey
Yu. Verbin, Dr. Tatjana V. Belopolskaya, Dr. Boris F. Borisov, Dr.
Roman V. Cherbunin, Dr. Nicholay G. Filosofov, Dr. Vladimir A.
Gaisin, Dr. Andrey V. Gartvik, Dr. Ilya Yu. Gerlovin, Dr. Roman V.
Grigor'ev, Dr. Natalya R. Grigor'eva, Dr. Natalya A. Grunina, Dr. Inna
S. Koltsova, Dr. Elena L. Lebedeva, Dr. Dmitriy K. Loginov, Dr.
Vladimir M. Mikushev, Dr. Alexey L. Pirozersky, Dr. Valery M.
Sarnatsky, Dr. Alexey Yu. Serov, Dr. Vadim G. Talalaev, Dr.
Nicholay N. Vasilyev, MS Michael Yu. Petrov
121
Main educational activity:
1. Physics;
2. Applied Physics and Mathematics
Master’ programs.
Condensed matter physics:
1. Solid state spectroscopy (Head - Hon. Prof. Boris V. Novikov)
2. Coherent phonons and NMR in solid state (Head - Prof.
Elena V. Charnaya)
Photoelectronics (in the frame of German-Russian program
ACOphys)
1. New materials and nanotechnologies (Head - Prof. Vadim F.
Aguekian)
2. Semiconductor physics and optoelectronics (Head - Hon.
Prof. Boris V. Novikov)
Lecture courses:
For Bachelors:
1. Crystal physics
2. Symmetry of molecules and crystals
3. Technics and computerization of optical experiment
4. Physics of disordered matters
5. Optical properties of semiconductors
6. Electrical properties of semiconductors
7. General acoustics
8. Ultrasound spectroscopy methods
9. Ultraacoustics and molecular acoustics
10. Radiospectroscopy
11. Introduction to the physics of low-dimensional crystal
systems
12. Phonons in semiconductors with various diimensionality
13. Physics of semiconductors and semiconductor devices
For Masters:
1. Solid state theory
2. Optical spectroscopy of solid state
3. Optics of low-dimensional systems
4. Physics and technology of epitaxial systems
5. Acoustics in solid state physics
122
6. Physics of inhomogeneous matters
7. Pulse methods of radiospectroscopy
8. Optical spectroscopy of planar semiconductor systems
9. Electronic states in semiconductor structures with interfaces
10. Computational physics concepts
11. Semiconductor technologies
12. Characterization methods of semiconductors
13. X-ray and electronic spectroscopy of solid state
14. Excitons in low-dimensional systems
15. Physics of semiconductor lasers
16. Introduction in photonics and optoelectronics
17. Semiconductor devices
18. Optics of surface
19. Theory of semiconductors
20. Luminescence of semiconductors
21. Solid state luminescence
22. Acoustics of porous matters
23. Physical mechanics of continuous matters
24. Phase transfers
25. Magnetooptical properties of semiconductors
26. Hyperfast spectroscopy of semiconductor heterostructures
27. Acoustics and NMR of low-dimensional systems
28. Magnetic properties of solid state
Research Topics
Excitonic
spectroscopy
of
semiconductors
and
nanostructures
Localization of excitons near crystal surfaces
Vibrational states in low-dimensional systems
Optical properties of semimagnetic semiconductors and
heterostructures
Excitonic states in disordered systems
Calorimetric study of the system water-biopolymer
Electron spin dynamics in semiconductor quantum wells and
quantum dots.
Mandelshtam-Brillouin spectroscopy of condensed matter.
Acoustic and NMR investigations of nanostructures.
Ultrasonic studies of phase transitions in condensed matter.
123
Special equipment:
Computerized diffractional spectrometers DFS
Raman spectrometer Jobine-Yvonne
Low temperature technics for optical measurements
Differential scanning calorimeter
NMR-spectrometer
Ultrasonic equipment
Mandelshtam-Brillouin spectrometer
Permanent collaboration with foreign universities and
institutes
1. National Cheng Kung University (Taiwan) – study of
superconductivity and ferroelectrics of nanocomposite
materials
2. Leipzig University (Germany) – NMR of condensed
matter
3. Wrotzlaw University (Poland) – Physics of condensed
matter
4. University of Agriculture, Cracow (Poland) Department
of Chemistry and Physics
5. Dortmund Technical University (Germany) – Spintronics
6. Ilmenau Technical University (Germany) – Spectroscopy
of nanoheterostructures
Selected Papers
1. A.Greilich, D.R.Yakovlev, A.Shabaev, Al.L.Efros, I.A.Yugova,
R.Oulton, V.Stavarache, D.Reuter, A.Wieck, M.Bayer “Mode
locking of electron spin coherences in singly charged
quantum dots” - Science, 313, 5785, 341-345 (2006);
2. Cheng Tien, Elena V. Charnaya, Wenya Wang,
Yu.A.Kumzerov, D.Michel “Possible liquid-liquid transition
of gallium in opal” - Phys. Rev. B 74, 024116 (2006);
124
3. V.F.Agekyan, N.N.Vasil'ev, A.Yu.Serov, Yu.A.Stepanov,
U.V.Tazaev, N.G.Filosofov, G.Karczewski “Radiative
recombination in Zn1-XMnXTe/Zn0.59Mg0.41Te quantum well
structures:
Exciton
emission
and
intracenter
luminescence” - Semiconductors, v. 40, № 1, p. 67-71
(2006);
4. A.Greilich, D.R.Yakovlev, I.A.Yugova, M.Bayer, A.Shabaev,
Al.L.Efros, D.Reuter, A.D.Wieck “Nuclei-induced frequency
focusing of electron spin coherence” – Science, 317,
5846, 1896-1899 (2007)
5. R.Oulton, A.Greilich, S.Yu.Verbin, R.V.Cherbunin, T.Auer,
D.R.Yakovlev,
M.Bayer,
I.A.Merkulov,
V.Stavarache,
D.Reuter, A.D.Wieck "Subsecond Spin Relaxation Times
in Quantum Dots at Zero Applied Magnetic Field Due to a
Strong Electron-Nuclear Interaction" - Phys.Rev.Lett, 98,
№ 10, p. 107401 (2007);
6. I.Ya.Gerlovin, Yu.P.Efimov, Yu.K.Dolgikh, S.A.Eliseev,
V.V.Ovsyankin, V.V.Petrov, R.V.Cherbunin, I.V.Ignatiev,
I.A.Yugova, L.V.Fokina, A.Greilich, D.R.Yakovlev, M.Bayer
“Electron-spin dephasing in GaAs∕Al0.34Ga0.66As quantum
wells with a gate-controlled electron density” - Phys. Rev.
B 75, 115330 (2007)
7. Bipul Pal, Sergey Y. Verbin, Ivan V. Ignatiev, Michio Ikezawa,
Yasuaki Masumoto "Nuclear-spin effects in singly
negatively charged InP quantum dots" - Phys. Rev. B, 75,
№ 12, p. 125322 (2007);
8. E.V.Charnaya, Cheng Tien, M.K.Lee, Yu.A.Kumzerov ”NMR
studies of metallic tin confined within porous matrices” Phys. Rev. B, 75, 144101 (2007);
9. E.V.Charnaya, Cheng Tien, M.K.Lee, Yu.A.Kumzerov
”Slowdown of self-diffusion induced by partial freezing
in confined liquid indium” - Phys. Rev. B, 75, 212202
(2007);
125
10. A.Greilich, M.Wiemann, F.G.G.Hernandez, D.R.Yakovlev,
I.A.Yugova, M.Bayer, A.Shabaev, Al.L. Efros, D.Reuter,
A.D.Wieck “Robust manipulation of electron spin
coherence in an ensemble of singly charged quantum
dots” – Phys. Rev. B 75, 233301 (2007)
11. I.A.Yugova, A.Greilich, D.R.Yakovlev, A.A.Kiselev, M.Bayer,
V.V.Petrov, Yu.K.Dolgikh, D.Reuter, A.D.Wieck “Universal
behavior of the electron g factor in GaAs∕AlxGa1−xAs
quantum wells” - Phys. Rev. B 75, 245302 (2007)
12. V.F.Agekyan, N.G.Filosofov, A.Yu.Serov, N.N.Vasiliev, I.Akai,
T.Karasawa, G.Karczewski “Mn2+ and band exciton
luminescence in ZnMnTe/ZnMgTe quantum well
structures” - physica status solidi (b):, v. 244, № 9, p. 32653270 (2007);
13. V.F.Agekyan, N.N.Vasiliev, A.Yu.Serov, N.G.Filosofov, I.Akai,
T.Karasawa, G.Karczewski “Exciton and intracenter
radiative recombination in ZnMnTe and CdMnTe
quantum wells with optically active manganese ions” Physics of the Solid State, v. 49, № 6, p. 1175-1183 (2007);.
14. I.Kh.Akopyan, M.E.Labzovskaya, B.V.Novikov, V.M.Smirnov,
“Metastable
modifications
in
mercury
diiodide
nanocrystals” - Physics of the Solid State 49, N7, 13751381 (2007)
15. V.G.Talalaev,
J.W.Tomm,
N.D.Zakharov,
P.Werner,
U.Gosele, B.V.Novikov, A.S.Sokolov, Y.B.Samsonenko,
V.A.Egorov, and G.E.Cirlin, «Transient carrier transfer in
tunnel injection structures» - Appl. Phys. Lett. v. 93, № 3,
031105, (2008);
16. M.Yu.Petrov,
I.V.Ignatiev,
S.V.Poltavtsev,
A.Greilich,
A.Bauschulte, D.R.Yakovlev, and M.Bayer «Effect of
thermal annealing on the hyperfine interaction in
InAs/GaAs quantum dots» - Physical Review B 78, № 4,
045315 (9 pages) (2008);
126
17. Belopolskaya T.V., Tsereteli G.I., Grunina N.A., Smirnova
O.I. “Calorimetric Study of The Native and Postdenatured
Structures in Starches With Different Degree of
Hydration” - J. Thermal.Analysis Calorimetry, v. 92,
p.677-682 (2008);
18. Tsereteli G.I., Belopolskaya T.V., Grunina N.A. “Dehydrated
Native Biopolymers an Unique Representative of
Glassy Systems” - J. Thermal.Analysis Calorimetry, v. 92,
p.711-716 (2008);
19. A.Greilich, S.Spatzek, I.A.Akimov, D.R.Yakovlev, M.Bayer,
I.A.Yugova, Al.L.Efros, D.Reuter, A.D.Wieck “Collective
single-mode precession of electron spins in an ensemble
of singly charged (In,Ga)As/GaAs quantum dots” – Phys.
Rev. B, v. 79, № 20, 201305, (2009);
20. Roman V. Cherbunin, Sergey Yu. Verbin, Thomas Auer,
Dmitri R. Yakovlev, Dirk Reuter, Andreas D. Wieck, Il'ya Ya.
Gerlovin, Ivan V. Ignatiev, Dmitry V. Vishnevsky, Manfred
Bayer "Dynamics of the nuclear spin polarization by
optically oriented electrons in a (In,Ga)As/GaAs quantum
dot ensemble" - Phys. Rev. B, 80, № 3, p. 035326 (2009);
21. I.A.Yugova, M.M.Glazov, E.L.Ivchenko, Al.L.Efros “Pumpprobe Faraday rotation and ellipticity in an ensemble of
singly charged quantum dots” - Phys. Rev. B, v. 80, № 10,
p. 104436 (2009);
22. M.Yu.Petrov, G.G.Kozlov, I.V.Ignatiev, R.V.Cherbunin,
D.R.Yakovlev, M.Bayer “Coupled electron-nuclear spin
dynamics in quantum dots: A graded box model
approach” - Phys. Rev. B 80, 125318 (2009)
23. T.Auer, R.Oulton, A.Bauschulte, D.R.Yakovlev, M.Bayer,
S.Yu.Verbin,
R.V.Cherbunin,
D.Reuter,
A.D.Wieck
"Measurement of the Knight field and local nuclear
dipole-dipole field in an InGaAs/GaAs quantum dot
ensemble" - Phys. Rev. B, 80, № 20, p. 205303 (2009);
127
24. E.V.Kolesnikova,
Y.V.Domracheva,
M.V.Zamoryanskaya,
I.Kh.Akopyan, B.V.Novikov, D.A.Tsagan-Mandjieva “Study of
ion diffusion in superionic crystals by EPMA and local CL” Superlattices and Microstructures, v. 45, № 4-5, p. 369-375 (2009);
25. V.F.Agekyan, A.Yu.Serov, Yu.A.Stepanov, N.G.Filosofov,
D.B.Bembitov, G.Karczewski “Radiative recombination in
the CdMgTe matrix with ultrathin narrow-gap CdMnTe
layers” - Semiconductors. 2009, v. 43, № 1, p. 57-62 (2009);
26. K.Flisinski,
I.Ya.Gerlovin,
I.V.Ignatiev,
M.Yu.Petrov,
S.Yu.Verbin, D.R.Yakovlev, D.Reuter, A.D.Wieck, M.Bayer
"Optically detected magnetic resonance at the
quadrupole-split nuclear states in (In,Ga)As/GaAs
quantum dots" - Phys. Rev. B, 82, № 8, p. 081300 (2010);
27. V. Aguekian, L. Sangaletti, M. C. Mozzati, G. Drera, L.
Floreano, A. Morgante, A. Goldoni, G. Karczewski. Local
electronic properties and magnetism of (Cd,Mn)Te
quantum wells. Appl. Phys. Lett. 96, 142105 (2010);
doi:10.1063/1.3378811
28. C. Tien, E. V. Charnaya, D. Y. Xing, A. L. Pirozerskii, Yu. A.
Kumzerov , Y. S. Ciou, M. K. Lee ”Vortex avalanches in a
Pb-porous glass nanocomposite” - Phys. Rev. B, 83, 1,
014502 (2011);
128
Terrestrial Physics
Professor Vladimir N. Troyan, Head of the Department
M.Sc. 1963, Ph.D. 1967, D.Sc. 1980
Research staff: Prof. Kovtun A.A., Head of the Laboratory of
geoelectricity; Prof. Vagin S.A., Prof. Semenov V.S., Head of the
Laboratory of physics of solar-terrestrial relations; Prof. Sergeev
V.A.; Prof. Yanovskaya T.B., Head of the Laboratory of seismology;
Prof. Kashtan B.M. Head of the Laboratory of dynamics of elastic
media
Dr. Apatenkov S.V.,
Dr. Bobrov N.Y,
Dr. Dmitrieva N.P.,
Dr. Dubyagin S.V.,
Dr. Zolotova N.V.,
Dr. Kiselev B.V.,
Dr. Kiselev Yu.V.,
Dr Kotikov
A.L.,
Dr. Krylov S.S.,
,
Dr. Kubyshkin I.V.,
Dr. Kubyshkina
M.V.,
Dr. Lebedeva V.V.,
Dr. Lyskova E.L.,
Dr. Mironova
I.A.,
Dr. Moiseev O.N.,
Dr. Petrov I.N., Dr. Petrova L.N., Dr. Samsonov A.A., Dr. Sergienko
E.S., Dr. Shukhtina M.A, Dr. Smirnova N.A., Dr. Smirnov M.Yu.,
Dr. Ponyavin D.I., Dr. Tsyganenko N.A.,Dr. Uspensky N.I.,
129
MASTER PROGRAM
PHYSICS OF SOLAR-TERRESTRIAL RELATIONSHIPS
Computer practicum
Master seminar
Practicum on geophysical data analysis and data processing
Lectures
Magnetosphere physics
Principles of nonlinear dynamics
Magnetosphere disturbances
Physics of high-latitude ionosphere and aurora phenomena
Data analysis and processing of geophysical information
Magnetic reconnection theory
Дисциплины по выбору
Additional chapters of MHD theory and plasma physics
Solar physics
Solar wind and its origin
Geomagnetic pulsations and ULF emissions
The role of magnetic fields in astrophysics
Numerical methods for MHD simulation
Space plasma physics
Master Prigram
Physics of the Earth
Qualification
Master of physics
Disciplines
Principles of the geophysical inverse problem solution
Special laboratory- сomputer exercises
Special seminar
Disciplines for master's program
Geothermics and radiometry
Theory of geophysical instruments
Data analysis and processing of geophysical information
General geology
Methods of geophysical prospecting
Computer exercises
130
Disciplines for choice
1. Electromagnetic methods in exploration geophysics
2. Asymptotic methods in the theory of seismic waves propagation
3. Numerical methods of wave field modeling for anisotropic elastic
media
4. Foundations of ferromagnetism
1. The theory of surface waves and free oscillation of the Earth
2. Matrix method in the theory of wave propagation in layered elastic
(solid and liquid) media
3. Analysis and interpretation of magnetotelluric data
4. Rock Magnetism
1. Physics of the seismic source
2.Countour integral method in dynamic theory of elasticity
3. Fractal models in geophysics
4. Paleo- and archeomagnetism
1. Inverse problems of seismology
2. Methods of diffractional seismic tomography
3. Direct and inverse problems of geoelectrics
4. Methods of reception of paleomagnetic information
1. Deep Earth geoelectrics
2. Ray seismic tomography
3. Seismic migration
4. Geomagnetic field and ways of its exploration
Research work
Research work
Research practice
Practice in applied geophysical methods
Practice in geology
Scientific and pedagogical practice
Preparation of the master thesis
131
Research topics
Laboratory of physics of solar-terrestrial relations: physics
of magnetosphere, solar physics, physics of ionosphere.
Laboratory of dynamics of elastic media: wave propagation
in complicated media, seismic inverse problems, seismic
prospecting.
Laboratory of seismology: investigation of internal structure of
the Earth with seismic methods.
Laboratory of geoelectricity: investigation of crust and higher
mantle conductivity.
Geomagnetic laboratory: paleomagnetic investigations, rock
magnetism.
Special equipment
Super-long-period noise-protected seismograph.
The Installation for Palaeointensity Determination with Step-by
Step
Remagnetization Metod.
The Magnetotelluric Station
Monographs:
1. Troyan V.N., Kiselev Yu. V. Statistical Methods of Geophysical
Data Processing. World Scientific Publishing, New Jersey,
London, Singapore, 2010, 436 p.
2. Troyan V.N., Kiselev Yu.V. Processing of Geophysical Data, St.
Petersburg, St. Petersburg State University, 2009, 566 p. (in
Russian)
3. T.B.Yanovskaya. Basic Seismology. SPbU press, 210 pp. 2008
Selected Papers:
1. S.A.Vagin, A.N.Kuznetsov. The role of physical modeling in
development of geoelectric science. //Geophysics, 2007 (in
Russian)
2. T.B.Yanovskaya, M.A.Geyer. Numerical method for surface
wave field calculations in the presence of caustics. News of
RAS, Earth Physics. №8. pp.35-43, 2007. (in Russian)
132
3.
Sormakov D.A., Sergeev V.A., Flux ropes topology in
magnetospheric plasma sheet from GEOTAIL data, Space
Research., 46, #5, pp.403-407, 2008 (in Russian).
4.
Koroleva T.Yu.,Королева Т.Ю., T.B.Yanovskaya, S.S.
Patrusheva, Seismic noise utilization for the exploration of Earth
crust and upper mantle structure, // News of RAS, Earth Physics.
#5. pp.2-14, 2009. (in Russian)
5.
T.B.Yanovskaya. The method of surface wave
tomography, based on data from distant earthquakes. // News of
RAS, Earth Physics, #2, pp.1-6, 2009. (in Russian)
6.
Samsonov A. A., O. Alexandrova, C. Lacombe, M.
Maksimovic, S. P. Gary, Proton temperature anisotropy in the
magnetosheath: comparison of 3-D MHD modelling with Cluster
data. Annales Geophysicae, v. 25, N 5, 1157-1173, 2007
7.
Apatenkov, S.V., V. A. Sergeev, M. V. Kubyshkina, R.
Nakamura, W. Baumjohann, A. Runov, I. Alexeev, A. Fazakerley, H.
Frey, S. Muhlbachler, P. W. Daly, J.-A. Sauvaud, N. Ganushkina, T.
Pulkkinen, G. D. Reeves, and Y. Khotyaintsev, Multi-spacecraft
observation of plasma dipolarization/injection in the inner
magnetosphere, Ann. Geophys., 25, 801–814, 2007
8.
N. A. Smirnova and M. Hayakawa, Fractal characteristics
of the ground-observed ULF emissions in relation to
geomagnetic and seismic activities, Journal of Atmospheric and
Solar-Terrestrial Physics, v. 69, pp. 1833-1841. 2007
9.
Sergeev V., V. Semenov, M.Kubyshkina, V.Ivanova,
W.Baumjohann, R.Nakamura, T. Penz, A. Runov, T. L. Zhang, K.-H.
Glassmeier, V. Angelopoulos, H. Frey, J.-A. Sauvaud, P. Daly, J. B.
Cao, H. Singer, and E. Lucek, Observations of repeated intense
near-Earth reconnection on closed field lines with Cluster,
Double Star and other spacecraft, Geophys. Res. Lett., vol. 34,
L02103, doi:10.1029/2006GL028452, 2007.
10.
Kubyshkina, M., T. I. Pulkkinen, N. Ganushkina, and N. A.
Partamies, Magnetospheric Currents During Sawtooth Events:
Event-Oriented Magnetic Field Model Analysis, J. Geophys. Res.,
113, A08211, doi:10.1029/2007JA012983, 2008
133
11.
V. A. Sergeev, N. A. Tsyganenko and V. Angelopoulos,
Dynamical response of the magnetotail to changes of the solar
wind direction: an MHD modeling perspective, Ann. Geophys.,
26, 2395–2402, 2008
12.
N. P. Dmitrieva, Cross-tail velocity component in the
plasma sheet fast flows, Ann. Geophys., 26, 1597-1604, 2008
13.
Korovinskiy, D. B., V. S. Semenov, N. V. Erkaev, A. V. Divin,
and H. K. Biernat, The 2.5-D analytical model of steady-state Hall
magnetic reconnection, J. Geophys. Res., 113, A04205,
doi:10.1029/2007JA012852, 2008
14.
Dyadechkin, S.A., V.S. Semenov, H.K. Biernat and T. Penz,
Comparison of magnetic flux tube and cosmic string behavior
in Kerr metric, Advances in Space Research, Vol.42, Issue 3,
pp.565-571, 2008
15.
Zolotova, N.V., D.I.Ponyavin, N.Marwan, and J.Kurths, Longterm asymmetry in the wings of the butterfly diagram//
Astronomy and Astrophysics. Vol.503. N 1. P.197-201. 2009.
16.
Kubyshkina, M., V. Sergeev, N. Tsyganenko, V.
Angelopoulos, A. Runov, H. Singer, K.H. Glassmeier, H.U. Auster,
W.
Baumjohann,
Toward
adapted
time-dependent
magnetospheric models: A simple approach based on tuning
the standard model// Journal of Geophysical Research. Vol.114,
A00C21, doi:10.1029/2008JA013547, 2009.
17.
Semenov, V., D. Korovinskiy, A. Divin, N. Erkaev, and H.
Biernat, Collisionless magnetic reconnection: Analytical model
and PIC simulation comparison, Annales Geophysicae, Vol.27,
Issue 3, pp.905-911, 2009
18.
Shukhtina, M.A., E.I. Gordeev, and V.A. Sergeev, Timevarying magnetotail magnetic flux calculation: a test of the
method// Annales Geophysicae. Vol.27. Issue 4. P.1583-1591.
2009.
19.
Tsyganenko, N.A., Magnetic field and electric currents in
the vicinity of polar cusps as inferred from Polar and Cluster
data// Annales Geophysicae. Vol.27, Issue 4. P.1573-1582. 2009.
134
20.
Dubyagin, S., V. Sergeev, S. Apatenkov, V. Angelopoulos, R.
Nakamura, J. McFadden, D. Larson, and J. Bonnell, Pressure and
entropy changes in the flow-braking region during magnetic
field dipolarization, J. Geophys. Res., 115, A10225,
doi:10.1029/2010JA015625, 2010.
21.
Shukhtina, M.A., V.A. Sergeev, A.D. DeJong, B. Hubert,
Comparison of magnetotail magnetic flux estimates based on
global auroral images and simultaneous solar wind—
magnetotail measurements, Journal of Atmospheric and SolarTerrestrial Physics, Vol.72, Issue 17, pp.1282-1291, 2010.
22.
I.G. Shevchenko, V. Sergeev, M. Kubyshkina, V.
Angelopoulos, K. H. Glassmeier, and H. J. Singer, Estimation of
magnetosphere‐ ionosphere mapping accuracy using isotropy
boundary and THEMIS observations, J. Geophys. Res., 115,
A11206, doi:10.1029/2010JA015354, 2010
23.
Selected Projects
International cooperation for the geophysical fields study
and their role in the exploration of the Earth and the
near-earth space and in the forecast of the catastrophes
(INTERGEOPHYSICS) #2.2.2.2.2190 Troyan V.N., Ministry
of Education Grant, 2006-2008.
The study of Earth, atmosphere and near-Earth space
(GEOCOSMOS). #2.1.1.4166 Timofeev Yu.M., Ministry of
Education Grant, 2006-2010. (together with department of
Atmosphere)
University Educational and Research Center “Modeling
and monitoring of the geospheres.” Zernov N.N., Ministry
of Education Grant, 2006-2010. (together with departments of
Atmosphere and Radiophysics)
Geophysical studies of Earth and near-Earth space
Yanovskaya T.B., Troyan V.N., Russian Federation President
Grant for leading scientific schools support, 2006-2009
135
136
The study of long-living dynamic plasma structures in
the Earth’s magnetosphere based on data of multispacecraft missions. #1595.2009.2. Apatenkov S.V.,
Russian Federation President Grant for young scientists,
2009-2010
String mechanism of energy release from Kerr black
hole. Dyadechkin S.A., Russian Federation President Grant
for young scientists, 2006-2007.
Magnetic reconnection in non-collisionless plasma in
Earth’s magnetosphere and space.Semenov V.S., Grant
RFBR 07-05-00776, 2007-2009.
The structure and dynamics of magnetospheric plasma
sheet during intensive energy loading.Sergeev V.A., Grant
RFBR 07-02-91703, 2007-2009
Surface wave tomography based on seismic noise:
application for study of Eastern-European Platform crust
and upper mantle. Yanovskaya T.B., Grant RFBR 08-0500355, 2008-2010
Study of seismic processes in the problems of the
medium imaging restoration. Troyan V.N., Grant RFBR 0805-00285, 2008-2010
Studies of magnetotail features and configuration
changes during substorms and reconnection Kubyshkina
M.V.., Grant RFBR 10-05-91163, 2010-2011.
Comparative study of plasma injections to the near-Earth
magnetosphere. Sergeev V.A., Grant RFBR 10-05-00223,
2010-2012
Spatial and temporal regularities in North –South Solar
asymmetry Zolotova N.V., Grant of St. Petersburg
Administration, 2009.
The behavior of aerosol layer in accordance with cosmic
rays ionization of atmosphere rate. Mironova I.A., Grant of
St. Petersburg Administration, 2009.
Department of Theoretical Physics
Professor V.M. Shabaev, Head of Quantum Mechanics Chair
Units:
Quantum Mechanics Chair
Chair of High Energy Physics and Elementary Particles
Statistical Physics Chair
Laboratory of Ultra-High Energy Physics
Laboratory of Quantum Networks
Quantum Mechanics Chair,
http://fock.phys.spbu.ru/english/index_en.htm
The chair is associated with Atomic and Molecular Theory
Laboratory
137
Academic and Research staff: Prof. V.M. Shabaev, Head of
Quantum Mechanics Chair; Sen. Res. V.I. Ochkur, Head of Atomic
and Molecular Theory Laboratory; Prof. I.V. Abarenkov; Prof. D.I.
Abramov; Prof. D.N. Aristov; Prof. Yu.Yu. Dmitriev; Prof. L.N.
Labzowsky; Prof. D.A. Telnov; Prof. I.I. Tupitsyn; Leading Res. P.A.
Braun; Leading Res. A.K. Kazansky; Leading Res. T.K. Rebane;
Leading Res. I.Yu. Yurova; Associate Prof. D.A. Glazov; Associate
Prof. I.A. Goidenko; Associate Prof. S.I. Nikitin; Associate Prof. N.N.
Penkina; Associate Prof. A.N. Petrov; Associate Prof. A.V.
Syromyatnikov; Sen. Res. O.Yu. Andreev; Res. V.G. Kuznetsov;
Res. V.F. Sharipov; Res. A.V. Volotka; Res. S.N. Zagoulaev;
Postdoctoral fellow N.S. Oreshkina; Postdoctoral fellow D.A.
Solovyev;
Master Degree Program “Quantum mechanics of atoms,
molecules and solids”.
PhD program:Theoretical physics, Physics of condensed matter
While studying at the Quantum Mechanics Division, the
students are taught courses in many areas of modern theoretical
quantum physics: theory of atoms and molecules, solid state theory,
collision theory, quantum chemistry, quantum electrodynamics,
quantum field theory. An emphasis is put on involvement of the
students in real research carried out at the Division in a variety of
directions, from development of new methods for calculations of
atoms, molecules and electronic structure of solids to tests of
modern theories of fundamental interactions. Many students
participate in international research collaboration and get training at
research centers abroad. This approach ensures that the students
get their education at highest international standards, and our
graduates are in high demand both in Russia and abroad. All the
students who express a desire and ability for research in theoretical
physics have an opportunity to continue their education in graduate
school. Fundamental education in quantum theory and the
widespread use of computer tools in the theoretical work guarantee
also good opportunities for employment in various companies
working in the field of high technologies, including information and
nanotechnology.
138
Research topics
Theory of atoms and molecules
Solid state theory
Quantum electrodynamics of highly charged ions
Tests of fundamental theories with atomic systems
Collision theory and dynamics of quantum systems
Quantum chaos
Selected papers 2007-2010
1. Volotka A.V., Glazov D.A., Shabaev V.M., Tupitsyn I.I.,
Plunien G. Screened QED corrections in lithiumlike heavy
ions in the presence of magnetic fields. Phys. Rev. Lett.
103 (2009) 033005.
2. Artemyev A.N., Shabaev V.M., Tupitsyn I.I., Plunien G.,
Yerokhin V.A. QED calculation of the 2p3/2 - 2p1/2
transition energy in boronlike argon. Phys. Rev. Lett. 98
(2007) 173004.
3. Labzowsky L., Schedrin G., Solovyev D., Plunien G.
Theoretical study of the accuracy limits of optical
resonance frequency measurements. Phys. Rev. Lett. 98
(2007) 203003.
4. Sharipov V., Labzowsky L., Plunien G. Excited States of the
Helium-Antihydrogen System. Phys. Rev. Lett. 98 (2007)
103001.
5. Tupitsyn I.I., Kozhedub Y.S., Shabaev V.M., Deyneka G.B.,
Hagmann S., Kozhuharov C., Plunien G., Stoehlker Th.
Relativistic
calculations
of
the
charge-transfer
probabilities and cross sections for low-energy
collisions of H-like ions with bare nuclei. Phys. Rev. A 82
(2010) 042701.
139
6. Goidenko I.A. QED corrections for the valence electron in
the heavy and superheavy metal atoms from the 11 and
12 groups. Eur. Phys. J. D 55 (2009) 35.
7. Abarenkov I.V. Unit cell for a lattice electrostatic potential.
Phys. Rev. B 76 (2007) 165127.
8. Abarenkov I.V., Zagoulaev S.N. Spin structure of the
reduced density matrix and spin polarized states. Int. J.
Quant. Chem. 108 (2008) 2657.
9. Zagoulaev S.N. Phenomenon of anti-Bragg magnetic
neutron diffraction. Europhysics Letters 91 (2010) 16003.
10. Trifonov E.D., Zagoulaev S.N. On the Bose-Einstein
condensate partition function for an ideal gas. PhysicsUspekhi 53 (2010) 83.
11. Kazansky A.K., Echenique P.M. One-electron model for the
electronic
response
of
metal
surfaces
to
subfemtosecond photoexcitation. Phys. Rev. Lett. 102
(2009) 177401.
12. Kazansky A.K., Kabachnik N.M., Sazhina I.P. Quantum
beats and fine structure in attosecond chronoscopy of
strong-field photoionization of atoms. Eur. Phys. Lett. 82
(2008) 13001.
13. Abramov D.I. Hyperspherical Coulomb spheroidal
representation in the Coulomb three-body problem. J.
Phys. B 41 (2008) 175201.
14. Braun P., Mueller S., Haake F. Semiclassical spectral
correlator in quasi one-dimensional systems. J. Phys. A:
Math. Theor. 41 (2008) 395101.
15. Gusarov S., Fedorova T.A., Dmitriev Yu.Yu., Kovalenko A.
On variational estimates for exchange-correlation
interaction obtained within super-CI approach to MCSCF
approximation. Int. J. of Quant. Chem. 109 (2009) 1672.
140
16. Rebane T.K. Energy bounds for a system of gravitating
bosons. Theor. and Math. Phys. 162 (2010) 347.
17. Telnov D.A., Chu S.I. Effects of electron structure and
multi-electron dynamical response on strong-field
multiphoton ionization of diatomic molecules with
arbitrary orientation: An all-electron time-dependent
density-functional-theory approach. Phys. Rev. A 79
(2009) 041401(R).
18. Telnov D.A., Chu S.I. Above-threshold-ionization spectra
from the core region of a time-dependent wave packet:
An ab initio time-dependent approach. Phys. Rev. A 79
(2009) 043421.
19. Syromyatnikov A.V. Collective excitations in a twodimensional antiferromagnet in a strong magnetic field.
Phys. Rev. B 79 (2009) 054413.
20. Aristov D.N., Bruenger C., Assaad F.F., Kiselev M.N.,
Weichselbaum A., Capponi S., Alet F. Asymmetric spin-1/2
two-leg ladders: Analytical studies supported by exact
diagonalization, DMRG, and Monte Carlo simulations.
Phys. Rev. B 82 (2010) 174410.
21. Aristov D.N., Woelfle P. Conductance through a potential
barrier embedded in a Luttinger liquid: Nonuniversal
scaling at strong coupling. Phys. Rev. B 80 (2009) 045109.
22. Shabaev V.M., Volotka A.V., Kozhuharov C., Plunien G.,
Stoehlker T. Parity- nonconservation effect with the laserinduced 2(3)S(1)-2(1)S(0) transition in heavy heliumlike
ions. Phys. Rev. A 81 (2010) 052102.
23. Shabaev V.M. Quantum electrodynamics of heavy ions
and atoms: current status and prospects. PhysicsUspekhi 51 (2008) 1175.
Selected Projects
1.
Quantum electrodynamical, electroweak and nuclear
structure effects in the theory of atoms, highly charged ions
and antiatoms. Prof. L.N. Labzowsky, Grant RFBR 05-02-17483a, 2005-2007.
141
2. Theoretical investigation of the fundamental interactions in
physics of atoms and multicharged ions.Prof. L.N. Labzowsky,
Grant RFBR 08-02-00026-a, 2008-2010.
3. Theoretical investigations of fundamental interactions in
atomic physics and astrophysics. Prof. L.N. Labzowsky,
Federal Special-purpose Programme "Scientific and sciencepedagogical personnel of innovative Russia", Grant No. P1334,
2009-2011.
4. Quantum electrodynamical effects in atomic systems. Prof.
V.M. Shabaev, Grant RFBR 04-02-17574-a, 2004-2006.
5. Quantum electrodynamics of heavy ions.Prof. V.M. Shabaev,
Grant RFBR 07-02-00126-a, 2007-2009.
6. Tests of fundamental theories in low-energy physics with
heavy ions. Prof. V.M. Shabaev, Grant RFBR-DFG 08-0291967_a, 2008-2009.
7. Quantum electrodynamic theory of the hyperfine structure
and the g-factor of highly charged ions. Prof. V.M. Shabaev,
Grant RFBR 10-02-00450-a, 2010-2012.
8. Atomic Physics with new Facilities at GSI. Prof. L.N.
Labzowsky, Prof. V.M. Shabaev, Grant INTAS-GSI, 06-10000128881, 2007-2008.
9. Tests of theories of fundamental interactions in physics of
atomic systems. Prof. V.M. Shabaev, Grant No. 2.1.1/1136, the
Ministry of Education and Science of Russian Federation:
Program for Development of Scientific Potential of High School,
2009-2010.
10. Quantum-chemical investigation of spin-polarized electronic
structure of magnetic materials. Prof. I.V. Abarenkov, Grant
RFBR, 2009-2011.
11. New Non-empirical Atomic Pseudopotential and it's
Application in the Quantum-Chemistry Calculations of
Molecules and Crystals. Prof. I.I.Tupitsyn, Grant RFBR 05-0332585-a, 2005-2007.93.
142
Department of High-Energy Physics and Elementary Particles,
The Chair is associated with the Research Laboratory of Nuclear
Professor, D. Sc. M.A.Braun,
Head of the Chair of High Energy Physics and Elementary
Particles
and Elementary Particle Theory.
Academic and Research staff: Prof. M.A.Braun, Head of High
Energy Physics and Elementary Particles Chair;
Prof. A.A.
Andrianov, Head of Nuclear and Elementary Particle Theory
Laboratory, Prof. V.A.Andrianov, Prof.N.V. Antonov; Prof. V.A.
Franke; Prof. M.V. Ioffe; Prof. L.N.Lipatov, Member-Corr. of RAS;
Prof. V.D. Lyakhovsky; Prof. S.N. Manida; Prof Yu.V.Novozhilov;
Prof V.Yu.Novozhilov; Prof. Yu.M. Pis’mak; Prof. L.V.Prokhorov;
Prof. V.V.Vechernin; Assoc. Prof. G.A.Chernykh; Assoc. Prof.
G.A.Feofilov;
Assoc.
Prof.
S.A.Paston;
Assoc.
Prof.E.V.Prokhvatilov; Assoc. Prof. V.V. Vereshagin; Assoc. Prof.
M.I.Viazovsky; Ass. I.V.Fialkowsky; Ass. A.V.Golovnev; Ass.
R.S.Kolevatov. Principal researcher D.V.Vassilevich; Senior
researcher S.S.Afonin; Senior researcher A.N.Manashov; Senior
researcher
V.N.Marachevsky;
Researcher
S.V.Shadchin;
Researcher A.N.Starodubtsev.
143
Theory of elementary particle interactions and quantum field
theory
PhD (graduate program) training of specialists in the VAK
nomenclature:
01.04.02 – Theoretical Physics
01.04.16– Physics of atomic nucleus and elementary particles
Basic special courses for students
1. Theory of elementary particles
2. Quantum electrodynamics
3. Theory of strong interactions
4. Quantum chromodynamics
5. Theory of weak interactions
6. Quantum theory of gravitation
7. Theory of nucleus
8. Group theory methods in quantum field theory
9. Application of quantum field theory in many-body problems.
10. Unperturbative quantum chromodynamics
11. Physics in spaces with extra dimensions
12. Experimental methods of high-energy physics
Key points of the Master Program
- the only chair in Russia with that name and profile
- training opportunities at universities and research centers in Russia
and Western Europe
- the cutting-edge research in the field of modern theoretical physics
and high-energy physics
- acquisition of real skills in research and computer modeling
- individual approach to the selection of training courses
- intensive study combined with practical research under supervision
of leading specialists
- individual research practices in leading research teams
- active use of computer, multimedia and information technologies in
educational process
144
Research topics
Quantum field theory and applications
Elementary particle theory
Quantum gravity
Quark structure of strongly interacting particles (hadrons)
Theory of strong interactions at high-energies
Physics in spaces with extra dimensions and non-commutative
coordinates
Application of group theory in elementary particle physics
Supersymmetry with applications to low-dimensional systems.
Selected papers 2007-2010
1. A.A. Andrianov and D. Espriu - ”Parity doubling from
Weinberg sum rules” - Phys. Lett. B, 671 (2009) 275-279;
2. A.A. Andrianov, F. Cannata, A.Y. Kamenshchik and D. Regoli
3.
4.
5.
6.
7.
- ”Two-field cosmological models and large-scale
magnetic fields” - J. Cosm. Astropart.Phys.(JCAP), 0810
(2008) 019 (15p.);
A.A. Andrianov and L. Vecchi - “On the stability of thick
brane worlds nonminimally coupled to gravity” - Phys.
Rev. D, 77 (2008) 044035 (10p.);
A.A. Andrianov - “Dual oscillators and Quantum
Pendulums: spectrum and correlators” - Phys. Rev. D, 76
(2007) 025003;
N.V.Antonov, V.I.Iglovikov, A.S.Kapustin – “Effects of
turbulent mixing on the nonequilibrium critical
behaviour” – Journal of Physics A, 42 (2009) 135001 (19p.);
N.Armesto, M.A.Braun and C.Pajares - "On the long-range
correlations in hadron-nucleus scattering" - Phys. Rev. C,
75 (2007) 054902;
S.Bondarenko and M.A.Braun - "Boundary conditions in the
QCD nucleus-nucleus scattering problem" - Nucl. Phys. A,
799 (2008) 151-166;
145
8. M.A.Braun - "Nucleus-nucleus cross sections and longrange correlations with a local supercritical pomeron" Nucl. Phys. A, 806 (2008) 230-244;
9. M.A.Braun and A.N.Tarasov - "Loops in the Reggeon model
for hA scattering" - Eur. Phys. J. C, 58 (2008) 383-394;
10. M.V.Ioffe, D.N.Nishnianidze - "Exact Solvability of TwoDimensional Real Singular Morse Potential" – Physical
Review A, 76 (2007) 052114 (5 p.p.);
11. M.V.Ioffe, J.Mateos Guilarte, P.A.Valinevich - "A Class of
Partially Solvable Two-Dimensional Quantum Models with
Periodic Potentials" – Nuclear Physics B, 790 (2008) 414431;
12. J.Bartels, L.N.Lipatov and A.S.Vera – “BFKL Pomeron,
Reggeized gluons, and Bern-Dixon-Smirnov amplitudes” Phys. Rev., D80 (2009) 045002;
13. J.Bartels, L.N.Lipatov, K.Peters, «The Pomeranchuk
singularity and vector boson reggeization in electroweak
theory», Nucl. Phys. B, 772, 103 (2007).
14. V.D.Lyakhovsky – “Twist deformations of kappa-Poincare
algebra” - Reports on Mathematical Physics, 61 (2008) 213220;
15. V.Novozhilov, Yu.Novozhilov – “Chiral Parametrization of
QCD Vector Field in SU(3)” - Modern Physics Letters A, 23
(2008) 3285-3297;
16. M.A.Shpot, H.W.Diehl, Yu.M.Pis’mak – “Compatibility of 1/n
and epsilon-expansions for critical exponents at m-axial
Lifshitz points” - J. Phys. A, 41 (2008) 135003 (7pp);
17. D.Grunewald, E.M.Ilgenfritz, E.V.Prokhvatilov, H.J.Pirner –
“Formulating Light Cone QCD on the lattice” – Physical
Review D, 77 (2008) 014512;
18. K.Semenov-Tian-Shansky, A.Vereshagin, V.Vereshagin –
“Bootstrap and the physical values of \piN resonance
parameters” - Physical Review D, 77 (2008) 025028 (20
pages);
146
19.
20. D.V.Vassilevich – “Divergences in the vacuum energy for
frequency-dependent interactions” – Physical Review D,
79 (2009) 065016 (11pp);
21. S.A.Paston and V.A.Franke – “Canonical formulation of
imbedded gravitation theory equivalent to general
relativity of Einstein” – Teor. Mat. Fiz., 153 (2007) 271-288;
22. S.S. Afonin - "Axial coupling from matching constituent
quark model to QCD" - Phys. Rev., C77 (2008) 058201;
23. A.Lambrecht and V.N.Marachevsky - “Casimir interaction of
dielectric gratings” - Phys.Rev.Lett., 101 (2008) 160403;
24. V.M. Braun, A.N. Manashov and J. Rohrwild – “Baryon
Operators of Higher Twist in QCD and Nucleon
Distribution Amplitudes” - Nucl.Phys.B, 807 (2009) 89-137;
25. I.V.Fialkovsky, V.N.Markov and Yu.M.Pis'mak – “Parity
violating cylindrical shell in the framework of QED” - J.
Phys.A, 41 (2008) 075403;
26. V.V.Vechernin and R.S.Kolevatov – “On correlation of
multiplicities and pt in ultrarelativistic ion collisions” –
Yad. Fiz., 70 (2007) 1846-1857;
Selected Projects
Federal Programme «Scientific and Educational Staff of
Innovational Russia»
2009-2013 “Methods of QFT for interactions of particles and
nuclei”;
Programme «The development of Scientific Potential of Higher
School»
(2009-2010) “Investigation of fundamental interactions by
methods of QFT and symmetry theory”;
147
148
Grant of President of Russia for support of leading scientific
Schools 2006-2007
“Theoretical study of physical properties of elementary particles
and atomic nuclei with high energy, mathematical problems of
QFT and their applications”;
Grants of Russian Foundation for Basic Researches – 3-4
grants annually.
Department of Statistical Physics,
Professor, D. Sc. A.K.Shchekin, Head of Statistical Physics
Chair
Academic and Research staff: Prof. A.K.Shchekin, Head of
Statistical Physics Chair; Prof. L.Ts. Adzhemyan; Prof. A.E. Kuchma;
Prof. F.M. Kuni; Prof. M.Yu. Nalimov; Prof. V.P.Romanov; Prof.
A.Yu. Val’kov; Prof. S.V. Ul’yanov; Principal Res. Prof. V.L. Kuzmin;
Principal Res. Prof. V.M. Uzdin; Principal Res. E.V. Aksenova;
Assoc. Prof. T.Yu. Novozhilova; Assoc. Prof. M.V. Komarova;
Sen. Instructor T.L. Kim; Sen. Res. V.A. Sverdlov; Sen. Res.
D.V. Tatyanenko; Ass. Prof. A.A. Lezova.
Profile of the Magister Degree Program “Statistical theory of
inhomogeneous systems”.
Candidate Degree (graduate program) training of specialists in the
VAK nomenclature:
01.04.02 – Theoretical Physics
01.04.07 – Physics of Condensed Matter
149
Basic special courses for students
1. Nonequilibrium statistical mechanics
2. Physical mechanics of continuous media
3. Theory of critical phenomena
4. Fundamentals of statistical description of fully developed
turbulence
5. Density functional approach in classical statistical mechanics
6. Waves and interactions in plasma of solids
7. Theory of quantum liquids
8. Collective Phenomena in Solids
9. Electronic properties of quantum-well systems
10. Kinetics of first-order phase transitions
11. Thermodynamics and kinetics of heterogeneous nucleation
12. Theory of micellization
13. Statistical theory of optical properties of inhomogeneous media
14. Theory of liquid crystals
15. Computing and modeling systems with many particles
16. Methods of computation of the functional integrals and lattice
models
Key points of the Magister Program
- the only chair in Russia with that name and profile
- magister's graduates may work in the areas of creation and
modeling of new materials (including micro-and nanoelectronics),
optical and X-ray diagnostics of various media
- training opportunities at universities in Russia and Western Europe
- the cutting-edge research in the field of modern theoretical physics
and condensed matter physics
- acquisition of real skills in research and computer modeling
- the individual approach to the selection of training courses
- individual research practices in leading research teams
- active use of computer, multimedia and information technologies in
educational process
150
Research topics
Application of the methods of quantum field theory to statistical
physics, critical phenomena
Thermodynamic and kinetic theory of first order phase transitions
theory, polymorphic transformations, and micellization
Theory of electron properties of low dimensional systems
Wave scattering and liquid crystals
Selected papers 2007-2010
1.
2.
3.
4.
5.
Adzhemyan L.Ts.,Antonov N.V.,Gol’din P.B.,
Kim T.L.
Kompaniets M.V. Renormalization group in the infinitedimensional turbulence: third-order results. J. Phys. A:
Math. Theor., v. 41, p. 495002 (2008).
Aksenova E.V., Kryukov E.V., Romanov V.P. Features of light
propagation in chiral media. JETP, v. 105, No. 6, p. 1259
(2007).
Aksenova E.V., Karetnikov A.A., Kovshik A.P., Kryukov E.V.,
Romanov V.P. Light propagation in chiral media with large
pitch. JOSA A, v. 25, No. 3, p. 600 (2008).
Aksenova E.V.,
Kryukov E.V.,
Romanov V.P.
Light
propagation in chiral media with large pitch. MCLC, v. 495,
p. 30/[382] (2008).
Aksenova E.V.,
Kuz’min V.L.,
Romanov V.P.,
Coherent
backscattering of light in nematic liquid crystals, JETP,
v. 108, No. 3, p. 516 (2009).
151
6.
7.
8.
9.
10.
11.
12.
13.
152
Gor G. Yu., Kuchma A. E. Steady-state composition of a twocomponent gas bubble growing in a liquid solution: selfsimilar approach J. Chem. Phys. Vol. 131, 234705 (2009),
Gor G. Yu., Kuchma A. E. Dynamics of gas bubble growth in
a supersaturated solution with Sievert's solubility law J.
Chem. Phys., Vol. 131, 034507 (2009),
Grinin A.P., Kuni F. M., Gor G.Yu. The rate of nonsteady gas
bubble growth in liquid supersaturated with gas. J. Mol. Liq.,
Vol. 148, No. 1, p. 32-34 (2009)
Grinin A.P., Gor G.Yu., Kuni F.M. Self-similar solution of a
nonsteady problem of nonisothermal vapour condensation
on a droplet growing in diffusion regime. Journal of Physical
Chemistry C, v. 112, No. 48, p. 19069 (2008).
Hnatich M., Adzhemyan L.T., Honkonen J. Improved epsilon
expansion in the theory of turbulence: summation of
nearest singularities by inclusion of an infrared irrelevant
operator. Eur. Phys. J. B, v. 73, p. 275 (2010).
Komarova M.V., Kremnev I.S., Nalimov M.Yu. Family of
instantons of the Kraichnan model with a frozen velocity
field. Theoret. and Math. Phys., v. 158, No. 2, p. 167 (2009).
Kshevetskiy M.S., Shchekin A.K. Nonlinear kinetics of fast
relaxation in solutions with short and lengthy micelles. J. Chem.
Phys., v. 131, p. 074114 (2009).
Kuchma A.E., Kuni F.M., Shchekin A.K. Nucleation stage with
nonsteady growth of supercritical gas bubbles in a strongly
supersaturated liquid solution and the effect of excluded
volume. Phys. Rev. E, v. 80, p. 061125 (2009).
14. Kuni F.M.,
15.
16.
17.
18.
19.
20.
21.
22.
Lezova A.A., Shchekin A.K. The laws of
establishing stationary composition in a droplet
condensing in a binary vapor-gas environment. Physica A:
Statistical Physics, v. 388, p. 3728 (2009).
Nalimov M.Yu., Sergeev V.A., Sladkoff L. Borel resummation
of the epsilon expansion of the dynamical exponent z in
model A of the $\phi^4(O(n))$ theory. Theor. and Math. Phys.,
v. 159, No. 1, p. 499 (2009).
Romanov V.P., Ulyanov S.V., Uzdin V.M., Nowak G., Vadala M.,
Zabel H. Information on in- and out-of-plane correlated
roughness in multilayers from x-ray specular reflectivity. J.
Phys. D: Appl. Phys., v. 41, p. 115401 (2008).
Romanov V.P.,
Ulyanov S.V.,
Uzdin V.M.,
Nowak G.,
Shokuie K., Zabel H. Separation of the diffuse contribution to
the specular x-ray scattering of multilayer films. Phys. Rev.
B, v. 82, p. 165416 (2010).
Rusanov A.I., Shchekin A.K. On the formulation of the
material equilibrium condition for a dissolving nanoparticle.
J. Chem. Phys., v. 127, p. 191102 (2007).
Rusanov A.I., Shchekin A.K., Tatyanenko D.V., Grand potential
in thermodynamics of solid bodies and surfaces. J. Chem.
Phys., v. 131, No. 16, p. 161104 (2009).
Rusanov A.I., Kuni F.M. Disjoining pressure at the edge of
plane-parallel slit between solids Interacting by dispersion
forces. Colloid Journal, v. 72, No. 1, p. 49 (2010).
Rusanov A.I., Tatyanenko D.V., Shchekin A.K., New Approach
to Defining Thermodynamic Surface Tension of Solids,
Colloid Journal, v. 72, No. 5, pp. 673–678 (2010).
Shchekin A.K., Rusanov A.I. Generalization of the GibbsKelvin-Kohler and Ostwald-Freundlich equations for a liquid
film on a soluble nanoparticle. J. Chem. Phys., v. 129. No. 15.
p. 154116 (2008).
153
23. Shchekin A.K., Shabaev I.V., Rusanov A.I. Thermodynamics
of droplet formation around a soluble condensation
nucleus in the atmosphere of a solvent vapor. J. Chem.
Phys., v. 129, No. 21, p. 214111 (2008).
24. Shchekin A.K.,Shabaev I.V., Activation barriers for the
complete dissolution of condensation nucleus and its
reverse crystallization in droplets in the undersaturated
solvent vapor. Colloid Journal, v. 72, No. 3, p. 432 (2010).
25. Shchekin A.K., Podguzova T.S., The modified Thomson
equation in the theory of heterogeneous vapor nucleation
on
charged
solid
particles,
Atmos.
Res.
doi:10.1016/j.atmosres.2010.10.006 (2010)
Selected Projects
Investigation of models of developed hydrodynamic
turbulence using field-theoretic methods, Grant RFBR 05-0217524, 2005-2007.
Evolution of nanoparticle’s structure during the process of
zol-gel synthesis at hydrothermal conditions, Grant RFBR 0608-01201, 2006-2008.
Anomalous optical phenomena in chiral liquid crystals
influenced by external actions at finite strength of the
surface anchoring, Grant RFBR 06-02-16287, 2006-2008.
Interface structure on the atomic scale in magnetic
nanosystems, Grant RFBR NNIO 06-02-04005, 2006-2008.
Noncollinear magnetism in metallic nanosystems, Grant
RFBR 06-02-16722, 2006-2008.
Fundamental problems of physics and chemistry of ultradispersed systems and interfaces, Grant of The Ministry of
Education and Science, RNP 2.1.1.1712, 2007-2008.
154
Research in quantum field theory of elementary particles,
nuclei and heterogeneous systems, The Ministry of Education
and Science, 2007-2009.
Kinetics of the formation of spherical micelles in solutions of
ionic surfactants, Grant RFBR 07-03-00245, 2007-2009.
Spatially inhomogeneous states in the metallic magnetic
nanosystems, Grant RFBR 07-02-01065, 2007-2009.
Critical phenomena and phase transitions in complex and
nonequilibrium systems, Grant RFBR 08-02-00125, 2008-2010.
Structure, thermodynamics and kinetics of supramolecular
systems, Grant of The Ministry of Education and Science, RNP
2.1.1/4430, 2009-2010.
Size effects in the theory of line tension and contact angles
of droplets of submicron size and partially wettable
substrates, Grant RFBR 09-03-01005, 2009-2010.
Development and creation of a physical tutorial on
computational research methods of molecular dynamics, The
Ministry of Education and Science, 2009.
The Frederiks effect in twist cells of helical liquid crystals,
Grant of the Government of Saint Petersburg, 2009.
Field-theoretical methods in the study of symmetry and the
dynamics of heterogeneous micro- and macrosystems. The
Ministry of Education and Science, 2010-2014.
A functional approach to the problems of phase transitions,
light scattering, and stochastic dynamics, The Ministry of
Education and Science, 2010-2011.
Development of computational tutorial on modeling of manyparticle systems, The Ministry of Education and Science, 2010.
Remagnetization processes of nanostructures, Grant RFBR
NNIO 10-02-91330, 2010.
155
The theory of a new phase particle growth, taking into
account the effects of nonstationarity, nonisothermality,
Stefan flow and the excluded volume, Grant RFBR 10-0300903, 2010-2012.
Anomalous polarization effects in multiple scattering of light
in optically active media, Prof. V.L. Kuzmin, Grant RFBR 10-0200937, 2010-2012.
156
Laboratory of Ultra-High Energy Physics,
http://alice03.spbu.ru/alice/group.shtml
Dr. Grigory Feofilov,
Head of the Laboratory of Ultra-High Energy
Physics Team Leader of the SPbSU group in
ALICE at the LHC, in NA57 and in NA61(SHINE)
experiments at the SPS at CERN
157
Research staff :
Angei Asryan – the Junior Scientific Researcher, PhD; Igor’ Alsybeev
– the Engineer, PhD student; Andrey Ivanov – the Junior Scientific
Researcher, PhD; Sergey Igolkin – the Leading Engineer; Ol’ga
Kochebina – the Engineer, MS student; Anatoly Kolojvari – the
Scientific Researcher; Valeriy Kondtratiev - the Seniour Scientific
Researcher, PhD; Igor’Lakomov – PhD student; Andrey Puchkov the Engineer; Dmitry Semenov – PhD student; Vladimir Vechernin–
the Leading Scientific Researcher, Dr.Sci., Leonid Vinogradov – the
Seniour Scientific Researcher, PhD; Andrey Zarochentsev – the
Leading GRID specialist.
Research topics
Experimental and theoretical study of strongly interacting matter
at extreme conditions.
Processes of multiparticle production in pp and AA interactions at
high energies.
Deconfinement. Phase transitions of nuclear matter. Theoretical
and Monte Carlo modeling of processes of pp and AA collisions.
Long-range correlations as a method to search for the new
physics phenomenon of quark-gluon string fusion.
Analysis of experimental data of ALICE at the Large Hadron
Collider(LHC) and NA61 at Super Proton Synchrotron at CERN
on the base of novel information technologies GRID and ROOT.
Application of Advanced Resource Connector (ARC/NorduGRID)
in scientific and educational processes.
158
Data treatment in the frameworks of the information platforms
AliROOT and the WLCG (the World Computing Grid for the
LHC). Search for new correlation phenomena in the ALICE and
NA61 data.
Modern event generators for the High Energy Physics (HEP) and
their applications (including the hadron therapy). Novel detectors
and technique for the modern HEP experiments.
Selected papers 2007-2010
1. Transverse momentum spectra of charged particles in
proton–proton collisions at √s=900 GeV with ALICE at the LHC.
By ALICE Collaboration (K. Aamodt et al.) Physics Letters B 693
53–68 (2010). Elliptic flow of charged particles in Pb-Pb collisions at
2.76 TeV By ALICE Collaboration (K. Aamodt et al.), Chargedparticle multiplicity density at mid-rapidity in central Pb-Pb collisions
at sqrt(sNN) = 2.76 TeV , By ALICE Collaboration (K. Aamodt et al.)
.Charged-particle
2. Charged-particle multiplicity measurement in proton-proton
collisions at sqrt(s) = 7 TeV with ALICE at LHC.By ALICE
Collaboration (K. Aamodt et al.). Published in Eur.Phys.J.C68:345354,2010.
3. Charged-particle multiplicity measurement in proton-proton
collisions at sqrt(s) = 0.9 and 2.36 TeV with ALICE at LHC.By
ALICE Collaboration (K. Aamodt et al.) Apr 2010. Published in
Eur.Phys.J.C68:89-108,2010.
4. First proton-proton collisions at the LHC as observed with
the ALICE detector: Measurement of the charged particle
pseudorapidity density at s**(1/2) = 900-GeV.By ALICE
Collaboration (K Aamodt et al.). Nov 2009. 15pp. Published in
Eur.Phys.J.C65:111-125,2010.
159
5. The ALICE experiment at the CERN LHC.By ALICE
Collaboration (K. Aamodt et al.). 2008. 259pp. Published in
JINST 3:S08002,2008.
6. p(t)-multiplicity correlations in a multi-Pomeron-exchange
model with string collective effects. N. Armesto, (Santiago de
Compostela U., IGFAE) , D.A. Derkach, G.A. Feofilov, Published in
Phys.Atom.Nucl.71:2087-2095,2008.
7. «Mean transverse momentum, multiplicity and their
correlation in pp collisions in string fusion model», V.
Vechernin, I. Lakomov, A. Puchkov, “Vestnik SPbSU”, ser.4, 2010,
vyp.3
8. "Long-Range Correlations between Transverse Momenta of
Charged Particles Produced in Relativistic Nucleus-Nucleus
Collisions", V.V. Vechernin, R.S. Kolevatov, Yad.Fiz. 70 (2007)
1858-1867. Phys. of Atom. Nucl. 70 (2007) 1809-1818.
160
Laboratory of Quantum Networks
Professor, D. Sc. Boris S.Pavlov, Head of the Laboratory
Ph.D. 1964, D.Sc. 1974.
Fellow of New Zealand Royal Society, 2004; Actual Member of
Academy of the Academy of the Natural Science, 2010.
Research staff: Dr. E.Sh.Gutshabash, Prof. Dr.P.B.Kurasov,
Prof. Dr. S.N.Naboko, MoS A.B. Mikhailova, Dr. V.L Oleinik,
Dr. A.A.Pokrovski, Dr. R.V.Romanov, Dr. P.N.Bibikov.
Research topics
Spectral Theory of Linear Operators and its
application to study of transport properties of
Quantum Networks, nano-elecronics,
acoustics
and few-body Scattering.
Asymptotic of Ortogonal Polynomials and spectrum
characteristics of the Hermitean Jacobi’s matrices.
161
Explicitly solvable models of Quantum Complex
Systems.
Theory of nonlinear Classical and Quantum
Integrable Systems and its Applications in
Mathematical Physics and Magnetism.
Theory of Complex Systems and it’s application to
financial markets and Chaotic Dynamics.
Selected papers
1. P.Bibikov. Zero-temperature magnetic-field-induced
phase transitions between two ordered gapped
phases
in spin-ladders with ferromagnetic legs.
Phys. Rev. B, 73, 2006, 132402.
2. A.Boutet de Monvel, S. Naboko, L.O. Silva. The asymptotic
behavior of eigenvalues of a modified Jaynes-Cummings
model. Asymptot. Anal. 47 ,, no. 3-4, 2006, pp.291-315.
3. A.Kiselev, S.Naboko. Nonself-adjoint operators with
almost Hermitian spectrum: matrix model. I. J. Comput.
Appl. Math. 194, 1, 2006, pp.115--130.
4. M. Aizenman, A. Elgart, S. Naboko, J. Schenker, G. Stolz.
Moment analysis for localization in random
Schrodinger operators. Invent. Math,. 163, 2, 2006,
pp.343--413.
5. S.Naboko, M. Solomyak. On the absolutely continuous
spectrum in a model of an irreversible quantum
graph. Proc. London Math. Soc. (3) , 92, 1, 2006,
pp.251--272.
6. P.Bibikov, M.Vyazovsky. Origin of the second coherent
peak in the dyn. struct, factor of an ass. spin ladder.
Phys.Rev.B., v.7, 2007, 094420.
7. P.Bibikov. R-matrices for integrable SU(2)*U(1)-symm.
S=1/2 spin-orb. chains. J.of Phys.A., 40, 2007, 4683
8. P.Bibikov. Magnon mode truncation in rang-dimirized
asymmetric spin ladder. Phys.Rev.B,
76, 2007,
p.174431.
162
9. P.Kurasov,
S.Naboko.
Wigner-von
Neimann
perturbations of a period. pot.:spectral singul. in
bands. Math. Proc. Cambr. Phyl. Soc., 142, 1, 2007,
pp.161-183.
10. B.Pavlov. A star graph model via operator extension.
Math. Proceed. Cambridge Phyl. Soc., v.142, 2007.
11. B.Pavlov, A. Yafyasov. Standing waves and resonance
transport mechanism in quantum networks. In: Surface
Science, 601, 2007, pp. 2712 -2716.
12. L. Petrova, B. Pavlov. Tectonic plate under a localized
boundary stress: fitting of a zero-range solvable
model. Journal of Physics A, 41 , 2008, 085206.
13. A.Pavlov.
Krein formula with compensated
singularities for DN- Mapping and the generalized
Kirchhoff Condition at the Neumann Schr"odinger
Junction. Russian J. of Mathematical Physics 15, 9
,2008, pp 361-389.
14. P.Kurasov. Graph Laplacians and Topology, Ark. Mat.,
46, 2008, pp. 95-111.
15. P.Kurasov. Schrodinger operators on graphs and
geometry I: essentially bounded potentials, J. Func.
Anal., 254, 2008, pp. 934-953.
16. S.Avdonin and P.Kurasov.
Inverse problems for
quantum trees, Inverse Problems and Imaging, 2, 2008,
pp. 1-21.
17. P. Bibikov. A three-magnon problem for exactly rungdimerized spin ladder: from a general outlook to the
Bethe ansatz" J. of Phys. A 42, 2009, 315212.
18. E.Gutshabash. Soliton dynamics in the Wess-ZuminoNovikov-Witten model. JETP Letters, v.89, 1, 2009, pp.1-5.
19. A.Pavlov. A solvable model for scattering on a junction
and a modified analytic perturbation procedure. In:
Operator Theory Advances and Applications, 197, 2009, pp.
281- 335.
163
20. A.Pavlov. Operator extensions, Friedrichs model and
some fitted zero-range models. In: MRIT workshop Math.
for-Industry Tutorial: Spectral theories of non-hermitian
operators and their application. Ed. Yasuhide Fukumoto,
Yasunori Maekawa, COE Lecture Notes Kyushu University,
20, 2009, pp. 57- 103.
21. B.Pavlov. A solvable model for scattering on a junction
and a modifed analytic perturbation procedure. In:
Characteristic functions, scattering functions and
transfer functions , 281336; Oper. Theory Adv. Appl., 197,
Birkhuser Verlag, Basel , 2010, pp 281- 335.
22. N. Bagraev, G. Martin, B. Pavlov.
Landau-Zener
Phenomenon on a double of weakly interacting quasi-2d
lattices. In: Progress in Computational Physics ( PiCP ),
2010, pp. 61-64.
23. P.Kurasov, Inverse problem for Aharonov - Bohm rings,
Math. Proc. Cambridge Philosophical Society, 148, 2010,
pp.331-362.
24. S.Avdonin, P.Kurasov and M.Nowaczyk, Inverse Problems
for Quantum Trees II Recovering Matching Conditions
for Star Graphs, Inverse Problems and Imaging, 4/4, 2010,
pp.579-598.
25. E.Gutshabash. On the equation on minimal surface in
R^3: various representations, properties of exact
solutions,conservations laws. J. of Math. Sciences, 168,
6, 2010, p.829.
Selected Projects
Advances in Scattering theory and solvable models.
Prof.B.S.Pavlov, Grant of Royal Society New Zealand,20102013.
Quantum systems investigation by means of Harmonic
analysis. Prof.B.S.Pavlov, Grant RFBR 09-01-00515a, 20092
164
Contents
SAINT PETERSBURG STATE UNIVERSITY
3
FACULTY OF PHYSICS
7
ACADEMICIAN VLADIMIR ALEKSANDROVICH FOCK
(1898-1974)
FACULTY OF PHYSICS IN NUMBERS
Physics of atmosphere
Computational Physics
General physics I (Quantum Electronics)
General Physics II (Chemical Physics)
Mathematics and Mathematical Physics
Molecular Biophysics
13
15
17
27
31
39
47
55
Molecular Spectroscopy
Nuclear Physics
Optics
Photonics
Polymer Physics
61
69
75
83
89
Quantum Magnetic Phenomena
Radiophysics
Solid State Electronics
Solid State Physics
Terrestrial Physics
Department of Theoretical Physics
Department of High-Energy Physics and Elementary
Particles
Department of Statistical Physics
Laboratory of Ultra-High Energy Physics
Laboratory of Quantum Networks
95
103
113
121
129
137
143
149
157
161
165
Related documents