Thermal Simulations, Open Boundary Conditions and Switches

SU (N ) gauge theories on compact spaces have a non-trivial vacuum structure characterized by a countable set of topological sectors and their topological charge. In lattice simulations, every topological sector needs to be explored a number of times which reflects its weight in the path integral. Current lattice simulations are impeded by the so-called freezing of the topological charge problem. As the continuum is approached, energy barriers between topological sectors become well defined and the simulations get trapped in a given sector. A possible way out was introduced by Luscher and Schaefer using open boundary condition in the time extent. However, this solution cannot be used for thermal simulations, where the time direction is required to be periodic. In this proceedings, we present results obtained using open boundary conditions in space, at non-zero temperature. With these conditions, the topological charge is not quantized and the topological barriers are lifted. A downside of this method are the strong finite-size effects introduced by the boundary conditions. We also present some exploratory results which show how these conditions could be used on an algorithmic level to reshuffle the system and generate periodic configurations with non-zero topological charge.

[1]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[2]  L. Infeld Quantum Theory of Fields , 1949, Nature.

[3]  B. Dewitt,et al.  Topology and quantum field theory , 1979 .

[4]  David J. Gross,et al.  QCD and instantons at finite temperature , 1981 .

[5]  M. Lüscher,et al.  Topology of lattice gauge fields , 1982 .

[6]  P. Braam,et al.  Nahm's transformation for instantons , 1989 .

[7]  S. Weinberg The Quantum Theory of Fields, Vol. 2: Modern Applications , 1996 .

[8]  A. ADoefaa,et al.  ? ? ? ? f ? ? ? ? ? , 2003 .

[9]  Comparison of |Q|=1 and |Q|=2 gauge-field configurations on the lattice four-torus , 2003, hep-lat/0306010.

[10]  Martin Lüscher,et al.  Properties and uses of the Wilson flow in lattice QCD , 2010 .

[11]  S. Schaefer,et al.  Critical slowing down and error analysis in lattice QCD simulations , 2010, 1009.5228.

[12]  S. Schaefer,et al.  Lattice QCD without topology barriers , 2011, 1105.4749.

[13]  T. Hatsuda,et al.  Complex heavy-quark potential at finite temperature from lattice QCD. , 2011, Physical review letters.

[14]  M. Wagner,et al.  Studying and removing effects of fixed topology , 2014, 1404.3597.

[15]  Z. Fodor,et al.  Axion cosmology, lattice QCD and the dilute instanton gas , 2015, 1508.06917.

[16]  P. Forcrand,et al.  The Slab Method to Measure the Topological Susceptibility , 2016, 1610.00685.

[17]  Gorjan Alagic,et al.  #p , 2019, Quantum information & computation.

[18]  G. Moore Axion dark matter and the Lattice , 2017, 1709.09466.

[19]  M. Hasenbusch Fighting topological freezing in the two-dimensional CPN-1 model , 2017, 1709.09460.

[20]  R. Sommer,et al.  SU(3) Yang Mills theory at small distances and fine lattices , 2017, 1711.01860.

[21]  Tsuyoshi Murata,et al.  {m , 1934, ACML.