Zeros of the partition function for 12 flavor QCD

Abstract

We consider a four dimensional SU(3) lattice gauge theory with 12 staggered fermions having identical masses and an unimproved action. Using sets of plaquette distributions for various inverse bare couplings β, we reconstruct the density of states with the Ferrenberg -Swendsen method and calculate the zeros of the partition in the complex β plane with bare quark masses mq = 0.02, 0.06, 0.08 and 0.1 for hypercubes of linear size L= 4, 6, 8, 10, and 12. Our hypothesis is that there is a line of first order transitions in the (mq,β) plane ending at a second order phase transition. We expect this transition to be in the 4D Ising, mean field, universality class. We fit the L dependence of the zeros with the lowest imaginary part using two (y = bL-d) and three (y = a + bL-d) parameter fits. For mq = 0.02 the results provide strong support for a first order phase transition (d=3.98(6), and a statistically compatible with 0). The results also indicate, with less statistical significance for mq=0.06, that the three other masses are above the critical value mqc. In addition, we suggest that the infinite volume gap for the lowest zero a, can be represented as a A(mq-mqc)B with mqc 0.05 and B 1. Given that there are only three data points with significant error bars, it is difficult to rule out the mean field value B=3/2. Combining this result with spectroscopic results by Jin and Mawhinney, indicates that the gap with real axis (Lee-Yang edge) scales roughly like mσ2, where mσ is the mass of the 0++ scalar which is also the lowest excitation.