Add to ORKGWe investigate the Fermi Liquid theory of high density QCD. Using the renormalization group (RG), we determine the behavior of effective fermion interactions near the Fermi surface. At sufficiently high densities the matching between the Fermi Liquid theory and QCD can be accomplished in perturbation theory and a reliable calculation of Cooper pair formation performed, modulo the existence of a magnetic screening mass for the gluon. The presence of a chemical potential leads to different RG flows for sub-components of the effective interactions which would ordinarily be linked by Lorentz invariance. We also study instanton-induced operators and find that near the Fermi surface they are likely to be subdominant relative to operators induced ...
We present an effective field theory for high density, low temperature QCD in the crystalline colour...
Infrared divergences from the exchange of dynamically screened magnetic gluons (photons) lead to the...
When nuclear matter reaches a high enough density, we expect that the nucleons will overlap so much ...
We consider the most general four fermion operators in QCD for two and three massless flavors and st...
At ultra-high density, matter is expected to form a degenerate Fermi gas of quarks in which there is...
We investigate the effect of long range magnetic interactions on the renormalization group (RG) evol...
We review recent work on the phase structure of QCD at very high baryon density. We introduce the ph...
We study an effective theory of QCD at high density in detail, including the finite temperature effe...
I discuss recent developments in our understanding of the color-superconducting phases of cold, dens...
We study finite density QCD in an approximation in which the interaction between quarks is modelled ...
The low-energy effective theories for the two- and three-flavorcolor-superconductors arising in the ...
We describe the effective lagrangian approach to the color superconductivity. The effective descript...
We describe the crystalline phase of color superconducting quark matter. This phase may occur in qua...
We develop the Ginzburg-Landau approach to comparing different possible crystal structures for the c...
The influence of different chemical potential for different flavors on color superconductivity is an...
We present an effective field theory for high density, low temperature QCD in the crystalline colour...
Infrared divergences from the exchange of dynamically screened magnetic gluons (photons) lead to the...
When nuclear matter reaches a high enough density, we expect that the nucleons will overlap so much ...
We consider the most general four fermion operators in QCD for two and three massless flavors and st...
At ultra-high density, matter is expected to form a degenerate Fermi gas of quarks in which there is...
We investigate the effect of long range magnetic interactions on the renormalization group (RG) evol...
We review recent work on the phase structure of QCD at very high baryon density. We introduce the ph...
We study an effective theory of QCD at high density in detail, including the finite temperature effe...
I discuss recent developments in our understanding of the color-superconducting phases of cold, dens...
We study finite density QCD in an approximation in which the interaction between quarks is modelled ...
The low-energy effective theories for the two- and three-flavorcolor-superconductors arising in the ...
We describe the effective lagrangian approach to the color superconductivity. The effective descript...
We describe the crystalline phase of color superconducting quark matter. This phase may occur in qua...
We develop the Ginzburg-Landau approach to comparing different possible crystal structures for the c...
The influence of different chemical potential for different flavors on color superconductivity is an...
We present an effective field theory for high density, low temperature QCD in the crystalline colour...
Infrared divergences from the exchange of dynamically screened magnetic gluons (photons) lead to the...
When nuclear matter reaches a high enough density, we expect that the nucleons will overlap so much ...