Random matrix theory and QCD at nonzero chemical potential

Chiral random matrix theory has recently been shown to provide a tool useful for both modeling chiral symmetry restoration in QCD and for providing analytic descriptions of the microscopic spectral content of lattice gauge simulations. The basic ideas of chiral random matrix theory and some recent r

SU(2) lattice gauge theory with four flavors of quarks is simulated at nonzero chemical potential p and temperature T and the results are compared to the predictions of Effective Lagrangians. Simulations on 164 lattices indicate that at zero T the theory experiences a second order phase transition t

We investigate the eigenvalue spectrum of the staggered Dirac matrix in two color QCD at nite chemical potential. The pro les of complex eigenvalues close to the origin are compared to a complex generalization of the chiral Gaussian Symplectic Ensemble, con rming its predictions for weak and strong

We present a quantitative analysis of the microscopic Dirac spectrum which is complex in the presence of a nonvanishing quark chemical potential. Data from quenched SU(3) lattice simulations for different volumes V and small values of the chemical potential p are compared to analytical predictions