English

Exploring Complex-Langevin Methods for Finite-Density QCD

High Energy Physics - Lattice 2015-10-22 v1

Abstract

QCD at non-zero chemical potential (μ\mu) for quark number has a complex fermion determinant and thus standard simulation methods for lattice QCD cannot be applied. We therefore simulate this theory using the Complex-Langevin algorithm with Gauge Cooling in addition to adaptive methods, to prevent runaway behaviour. Simulations are performed at zero temperature on a 12412^4 lattice with 2 quarks which are light enough that mN/3m_N/3 is significantly larger than mπ/2m_\pi/2. Preliminary results are qualitatively as expected. The quark-number density is close to zero for μ<mN/3\mu < m_N/3, beyond which it increases, eventually reaching its saturation value of 33 for μ\mu sufficiently large. The chiral condensate decreases as μ\mu is increased approaching zero at saturation, while the plaquette increases towards its quenched value. We have yet to observe the transition to nuclear matter at μmN/3\mu \approx m_N/3, presumably because the runs for μ\mu between mN/3m_N/3 and saturation have yet to equilibrate.

Keywords

Cite

@article{arxiv.1510.06367,
  title  = {Exploring Complex-Langevin Methods for Finite-Density QCD},
  author = {D. K. Sinclair and J. B. Kogut},
  journal= {arXiv preprint arXiv:1510.06367},
  year   = {2015}
}

Comments

Latex, 7 pages, 4 postscript figures. Talk presented at Lattice 2015, Kobe, Japan

R2 v1 2026-06-22T11:25:54.777Z