Spin supercurrents and torquing with majorana fermions
... J. Alicea, Y. Oreg, G. Refael, F. von Oppen & M. P. A. Fisher, Nature Physics 7, 412–417 (2011) ...
... J. Alicea, Y. Oreg, G. Refael, F. von Oppen & M. P. A. Fisher, Nature Physics 7, 412–417 (2011) ...
Department of Chemistry - The City College of New York
... Office: MR-1120; Laboratory: MR-1122, -1124 and -1111B R. J. Silbey, R. A. Alberty and M. G. Bawendi, Physical Chemistry, John Wiley & Sons, Inc., 4th Edition, 2005. COURSE DESCRIPTION ...
... Office: MR-1120; Laboratory: MR-1122, -1124 and -1111B R. J. Silbey, R. A. Alberty and M. G. Bawendi, Physical Chemistry, John Wiley & Sons, Inc., 4th Edition, 2005. COURSE DESCRIPTION ...
The exotic world of quantum matter
... J. Bardeen, L. Cooper, R. Schrieffer (1957); Nobel prize 1971 ...
... J. Bardeen, L. Cooper, R. Schrieffer (1957); Nobel prize 1971 ...
Limitations of Quantum Advice and One-Way
... (Won’t say any more about this one) Ambainis: Suppose Alice has x,yFp and Bob has a,bFp. They want to know whether yax+b. 1-way quantum communication complexity? ...
... (Won’t say any more about this one) Ambainis: Suppose Alice has x,yFp and Bob has a,bFp. They want to know whether yax+b. 1-way quantum communication complexity? ...
Parallel Universes
... 1.This type of parallel universes is sort of a catch-all for other mathematical structures which we can conceive of, but which we don't observe as physical realities in our universe. 2.The Level 4 parallel universes are ones which are governed by different equations from those that govern our univer ...
... 1.This type of parallel universes is sort of a catch-all for other mathematical structures which we can conceive of, but which we don't observe as physical realities in our universe. 2.The Level 4 parallel universes are ones which are governed by different equations from those that govern our univer ...
the heisenberg uncertainty relation derived by multiplying matter
... front or the rear of the wave of the photon wave which is proportional to the wave length. The matter wavelength can be explained as the probability of uncertainty in measuring a quantum with the unit of length. The second beam of photon may hit a different spot from the first one because of the rot ...
... front or the rear of the wave of the photon wave which is proportional to the wave length. The matter wavelength can be explained as the probability of uncertainty in measuring a quantum with the unit of length. The second beam of photon may hit a different spot from the first one because of the rot ...
Parallel Universes
... 1.This type of parallel universes is sort of a catch-all for other mathematical structures which we can conceive of, but which we don't observe as physical realities in our universe. 2.The Level 4 parallel universes are ones which are governed by different equations from those that govern our univer ...
... 1.This type of parallel universes is sort of a catch-all for other mathematical structures which we can conceive of, but which we don't observe as physical realities in our universe. 2.The Level 4 parallel universes are ones which are governed by different equations from those that govern our univer ...
Document
... of freedom as electron spin and suggested a physical interpretation of particles spinning around their own axis. • 1926 – Enrico Fermi & Paul Dirac – formulated (independently) the Fermi-Dirac statistics, which describes distribution of many identical particles obeying the Pauli exclusion principle ...
... of freedom as electron spin and suggested a physical interpretation of particles spinning around their own axis. • 1926 – Enrico Fermi & Paul Dirac – formulated (independently) the Fermi-Dirac statistics, which describes distribution of many identical particles obeying the Pauli exclusion principle ...
B.7 Uncertainty principle (supplementary) - UTK-EECS
... P, Q that do not commute. That is, to the extent they do not commute, to that extent you cannot measure them both (because you would have to do either P Q or QP , but they do not give the same result). The best interpretation of the uncertainty principle is that if you set up the experiment multiple ...
... P, Q that do not commute. That is, to the extent they do not commute, to that extent you cannot measure them both (because you would have to do either P Q or QP , but they do not give the same result). The best interpretation of the uncertainty principle is that if you set up the experiment multiple ...
Discrete-continuous and classical-quantum
... precise line spectra and only Quantum Mechanics can explain this phenomenon. In fact the birth of quantum physics involves more discretization than discretness : in the famous Max Planck’s paper of 1900, and even more explicitly in the 1905 paper by Einstein about the photo-electric effect, what is ...
... precise line spectra and only Quantum Mechanics can explain this phenomenon. In fact the birth of quantum physics involves more discretization than discretness : in the famous Max Planck’s paper of 1900, and even more explicitly in the 1905 paper by Einstein about the photo-electric effect, what is ...
Many-body Quantum Mechanics
... the method of using annihilation and creation operators acting on a Fock space as ”second quantization”. As should be clear from the above, this terminology is misleading in the sense that ψ̂ is not a once more quantized version of the wave function, but an object which is directly (or via a Fourier ...
... the method of using annihilation and creation operators acting on a Fock space as ”second quantization”. As should be clear from the above, this terminology is misleading in the sense that ψ̂ is not a once more quantized version of the wave function, but an object which is directly (or via a Fourier ...
QUANTUM NUMBERS
... For an electron in an atom with l=0 is said to be in an s state. For an electron in an atom with l=1 is said to be in an p state. For an electron in an atom with l=2 is said to be in an d state. For an electron in an atom with l=3 is said to be in an e state. ...
... For an electron in an atom with l=0 is said to be in an s state. For an electron in an atom with l=1 is said to be in an p state. For an electron in an atom with l=2 is said to be in an d state. For an electron in an atom with l=3 is said to be in an e state. ...
6 Compact quantum spaces: “fuzzy spaces”
... In principle, such considerations should apply to all matrix geometries under consideration here, although the explicit realization of such coherent states is in general not known. All this illustrates the fact that for scales larger than �, these quantum spaces look like ordinary spaces. The quantu ...
... In principle, such considerations should apply to all matrix geometries under consideration here, although the explicit realization of such coherent states is in general not known. All this illustrates the fact that for scales larger than �, these quantum spaces look like ordinary spaces. The quantu ...