Lattice quantum chromodynamics at large isospin density: 6144 pions in a box

TL;DR

This paper introduces a stable algorithm for calculating large numbers of pion correlation functions in lattice QCD, enabling exploration of high isospin densities and revealing phase transition signatures and thermodynamic properties.

Contribution

The authors develop a numerically stable, efficient algorithm for computing correlation functions of many identical mesons, facilitating studies at large isospin densities in lattice QCD.

Findings

Observation of a peak in energy density at μ_I ≈ 1.5 m_π indicating a phase transition.

Large isospin chemical potential leads to deviations from ideal gas behavior.

Correlation functions are well approximated by log-normal distributions, aiding energy extraction.

Abstract

We present an algorithm to compute correlation functions for systems with the quantum numbers of many identical mesons from lattice quantum chromodynamics (QCD). The algorithm is numerically stable and allows for the computation of $n$-pion correlation functions for $n \in \{ 1, \dots, N\}$ using a single $N \times N$ matrix decomposition, improving on previous algorithms. We apply the algorithm to calculations of correlation functions with up to 6144 $\pi^+$s using two ensembles of gauge field configurations generated with quark masses corresponding to a pion mass $m_\pi = 170$ MeV and spacetime volumes of $(4.4^3\times 8.8)\ {\rm fm}^4$ and $(5.8^3\times 11.6)\ {\rm fm}^4$. We also discuss statistical techniques for the analysis of such systems, in which the correlation functions vary over many orders of magnitude. In particular, we observe that the many-pion correlation functions are well approximated by log-normal distributions, allowing the extraction of the energies of these systems. Using these energies, the large-isospin-density, zero-baryon-density region of the QCD phase diagram is explored. A peak is observed in the energy density at an isospin chemical potential $\mu_I\sim 1.5 m_\pi$, signalling the transition into a Bose-Einstein condensed phase. The isentropic speed of sound in the medium is seen to exceed the ideal-gas (conformal) limit ($c_s^2\leq 1/3$) over a wide range of chemical potential before falling towards the asymptotic expectation at $\mu_I\sim 15 m_\pi$. These, and other thermodynamic observables, indicate that the isospin chemical potential must be large for the system to be well described by an ideal gas or perturbative QCD.