Prerequisites Level Year Number of Study Hours Course Code
... bremsstrahlung, Photon interaction with matter, Photoelectric, Compton and pair production mechanism, Interaction of neutrons with matter, Interaction of hadrons with matter (briefly). Particle Detection: Ionization detectors, Ionization counters, proportional counters and Geiger Muller counters, Sc ...
... bremsstrahlung, Photon interaction with matter, Photoelectric, Compton and pair production mechanism, Interaction of neutrons with matter, Interaction of hadrons with matter (briefly). Particle Detection: Ionization detectors, Ionization counters, proportional counters and Geiger Muller counters, Sc ...
do physics online from quanta to quarks high
... distinct scattering centres are found inside each particle. For example, in the 1960's experiments like the Rutherford scattering of alpha particles from gold atoms were performed but this time with high energy electrons were scattered off protons. The results also produced larger deflections then w ...
... distinct scattering centres are found inside each particle. For example, in the 1960's experiments like the Rutherford scattering of alpha particles from gold atoms were performed but this time with high energy electrons were scattered off protons. The results also produced larger deflections then w ...
The Royal Society of Edinburgh The Large Hadron Collider – What It
... running period in 2013 with the discovery of the Higgs boson. Since then, the LHC has undergone a major upgrade and is due to start its second running period in 2015. This talk explained the importance of the Higgs boson discovery and looked at what the LHC will hope to find in the next three years. ...
... running period in 2013 with the discovery of the Higgs boson. Since then, the LHC has undergone a major upgrade and is due to start its second running period in 2015. This talk explained the importance of the Higgs boson discovery and looked at what the LHC will hope to find in the next three years. ...
An Overview of the Field of High Energy Physics
... • Supersymmetry would fix this problem but would introduce hundreds of new particles. • Neutrinos have mass! That breaks the standard model. • Why are there only three generations of quarks and leptons? • Are there only 4 space-time dimensions? • No easy way to incorporate gravity... ...
... • Supersymmetry would fix this problem but would introduce hundreds of new particles. • Neutrinos have mass! That breaks the standard model. • Why are there only three generations of quarks and leptons? • Are there only 4 space-time dimensions? • No easy way to incorporate gravity... ...
pdf
... gases of atoms cooled down to less than a millionth of a degree above absolute zero. These atomic clouds, 1011 times larger than atomic nuclei and 1011 times smaller than white dwarfs, can serve as a platform for studying under well-controlled conditions the same fundamental physics that occurs in t ...
... gases of atoms cooled down to less than a millionth of a degree above absolute zero. These atomic clouds, 1011 times larger than atomic nuclei and 1011 times smaller than white dwarfs, can serve as a platform for studying under well-controlled conditions the same fundamental physics that occurs in t ...
quarks
... 1933-34 Yukawa combines relativity and quantum theory to describe nuclear interactions by an exchange of new particles (mesons called "pions") between protons and neutrons. From the size of the nucleus, Yukawa concludes that the mass of the conjectured particles (mesons) is about 200 electron masses ...
... 1933-34 Yukawa combines relativity and quantum theory to describe nuclear interactions by an exchange of new particles (mesons called "pions") between protons and neutrons. From the size of the nucleus, Yukawa concludes that the mass of the conjectured particles (mesons) is about 200 electron masses ...
The relevance of proton-proton physics for the understanding
... non-isotropic string decay (JETSET) for production mechanism. Clustering favors baryon production JETSET is clearly favored by the data. Correlated L-Lbar pairs are produced predominantly in the same jet, i.e. short range compensation of quantum numbers. ...
... non-isotropic string decay (JETSET) for production mechanism. Clustering favors baryon production JETSET is clearly favored by the data. Correlated L-Lbar pairs are produced predominantly in the same jet, i.e. short range compensation of quantum numbers. ...
Lecture 1
... 1973 First indications of weak interactions with no charge exchange (due to Z0 exchange.) A quantum field theory of strong interaction is formulated (QCD) Politzer, Gross, and Wilczek discover that the color theory of the strong interaction has a special property, now called “asymptotic freedom.” 19 ...
... 1973 First indications of weak interactions with no charge exchange (due to Z0 exchange.) A quantum field theory of strong interaction is formulated (QCD) Politzer, Gross, and Wilczek discover that the color theory of the strong interaction has a special property, now called “asymptotic freedom.” 19 ...
High Density Quark Matter and Color Superconductivity
... fermions, QCD is a non-abelian gauge theory under SU(3) gauge. It has well tested and agreed with many experimental evidence over 30 years. However the phase diagram for QCD matter has not been well studied yet. The phase of the quark matter is depended on the temperature T and the chemical potentia ...
... fermions, QCD is a non-abelian gauge theory under SU(3) gauge. It has well tested and agreed with many experimental evidence over 30 years. However the phase diagram for QCD matter has not been well studied yet. The phase of the quark matter is depended on the temperature T and the chemical potentia ...
Reevaluation of dark matter direct detection rate
... contribution comes from quark momentum around squark or neutralino mass. On the other hand, in (d), it is around quark mass. ...
... contribution comes from quark momentum around squark or neutralino mass. On the other hand, in (d), it is around quark mass. ...
Strangeness production
Strangeness production is a signature and a diagnostic tool of quark–gluon plasma (or QGP) formation and properties. Unlike up and down quarks, from which everyday matter is made, strange quarks are formed in pair-production processes in collisions between constituents of the plasma. The dominant mechanism of production involves gluons only present when matter has become a quark–gluon plasma. When quark–gluon plasma disassembles into hadrons in a breakup process, the high availability of strange antiquarks helps to produce antimatter containing multiple strange quarks, which is otherwise rarely made. Similar considerations are at present made for the heavier charm flavor, which is made at the beginning of the collision process in the first interactions and is only abundant in the high-energy environments of CERN's Large Hadron Collider.