Electric conductivity in finite-density SU(2) lattice gauge theory with dynamical fermions

Abstract

We study the dependence of the electric conductivity on chemical potential in finite-density SU(2) gauge theory with Nf = 2 flavours of rooted staggered sea quarks, in combination with Wilson-Dirac and Domain Wall valence quarks. The pion mass is reasonably small with mπ/m ≈ 0.4. We concentrate in particular on the vicinity of the chiral crossover, where we find the low-frequency electric conductivity to be most sensitive to small changes in fermion density. Working in the low-density QCD-like regime with spontaneously broken chiral symmetry, we obtain an estimate of the first nontrivial coefficient c(T) of the expansion of conductivity σ(T,μ) = σ(T,0) (1 + c(T) (μ/T)2 + O(μ4)) in powers of μ, which has rather weak temperature dependence and takes its maximal value c(T) ≈ 0.10 0.07 around the critical temperature. At larger densities and lower temperatures, the conductivity quickly grows towards the diquark condensation phase, and also becomes closer to the free quark result. As a by-product of our study we confirm the conclusions of previous studies with heavier pion that for SU(2) gauge theory the ratio of crossover temperature to pion mass Tc/mπ ≈ 0.4 at μ=0 is significantly smaller than in real QCD.