Abstract
In the ε-regime of chiral perturbation theory the spectral correlations of the Euclidean QCD Dirac operator close to the origin can be computed using random matrix theory. To incorporate the effect of temperature, a random matrix ensemble has been proposed, where a constant, deterministic matrix is added to the Dirac operator. Its eigenvalue correlation functions can be written as the determinant of a kernel that depends on temperature. Due to recent progress in this specific class of random matrix ensembles, featuring a deterministic, additive shift, we can determine the limiting kernel and correlation functions in this class, which is the class of polynomial ensembles. We prove the equivalence between this new determinantal representation of the microscopic eigenvalue correlation functions and existing results in terms of determinants of different sizes, for an arbitrary number of quark flavours, with and without temperature, and extend them to non-zero topology. These results all agree and are thus universal when measured in units of the temperature dependent chiral condensate, as long as we stay below the chiral phase transition.
Highlights
At next-to-leading order in εχPT the low energy constants (LEC) merely have to be renormalised by finite volume corrections [18,19,20], keeping the equivalence to random matrices intact
We prove the equivalence between this new determinantal representation of the microscopic eigenvalue correlation functions and existing results in terms of determinants of different sizes, for an arbitrary number of quark flavours, with and without temperature, and extend them to non-zero topology
These results all agree and are universal when measured in units of the temperature dependent chiral condensate, as long as we stay below the chiral phase transition
Summary
We will recall the schematic ensemble [32, 33] of random matrices for QCD at non-zero temperature, with Nf massive quark flavours and fixed topology ν ≥ 0. We first give the matrix representation and derive the joint density of Dirac operator eigenvalues in subsection 2.1, which will be the starting point of our analysis. A critical difference regarding the integrable structure of the model at zero and non-zero temperature is pointed. Out, before in subsection 2.2 we give the general result for all k-point correlation functions at finite matrix size N in terms of the kernel as a double integral, applying results from [51]
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