Towards a parameter-free determination of critical exponents and chiral phase transition temperature in QCD
Abstract
In order to quantify the universal properties of the chiral phase transition in (2+1)-flavor QCD, we make use of an improved, renormalized order parameter for chiral symmetry breaking which is obtained as a suitable difference of the 2-flavor light quark chiral condensate and its corresponding light quark susceptibility. Having no additive ultraviolet as well as multiplicative logarithmic divergences, we use ratios of this order parameter constructed from its values for two different light quark masses. We show that this facilitates determining in a parameter-independent manner, the chiral phase transition temperature Tc and the associated critical exponent δ which, for sufficiently small values of the light quark masses, controls the quark mass dependence of the order parameter at Tc. We present first results of these calculations from our numerical analysis performed with staggered fermions on Nτ=8 lattices.
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