Orbifold equivalence and the sign problem at finite Baryon density

Aleksey Cherman; Masanori Hanada; Daniel Robles-Llana

doi:10.1103/PhysRevLett.106.091603

Orbifold equivalence and the sign problem at finite Baryon density

Aleksey Cherman, Masanori Hanada, Daniel Robles-Llana

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Abstract

We point out that SO(2N_c) gauge theory with N_f fundamental Dirac fermions does not have a sign problem at finite baryon number chemical potential μ_B. One can thus use lattice Monte Carlo simulations to study this theory at finite density. The absence of a sign problem in the SO(2N_c) theory is particularly interesting because a wide class of observables in the SO(2N_c) theory coincide with observables in QCD in the large N_c limit, as we show using the technique of large N_c orbifold equivalence. We argue that the orbifold equivalence between the two theories continues to hold at finite μ_B provided one adds appropriate deformation terms to the SO(2N_c) theory. This opens up the prospect of learning about QCD at finite μ_B using lattice studies of the SO(2N_c) theory.

Original language	English (US)
Article number	091603
Journal	Physical review letters
Volume	106
Issue number	9
DOIs	https://doi.org/10.1103/PhysRevLett.106.091603
State	Published - Mar 3 2011
Externally published	Yes

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title = "Orbifold equivalence and the sign problem at finite Baryon density",

abstract = "We point out that SO(2Nc) gauge theory with Nf fundamental Dirac fermions does not have a sign problem at finite baryon number chemical potential μB. One can thus use lattice Monte Carlo simulations to study this theory at finite density. The absence of a sign problem in the SO(2Nc) theory is particularly interesting because a wide class of observables in the SO(2Nc) theory coincide with observables in QCD in the large Nc limit, as we show using the technique of large Nc orbifold equivalence. We argue that the orbifold equivalence between the two theories continues to hold at finite μB provided one adds appropriate deformation terms to the SO(2Nc) theory. This opens up the prospect of learning about QCD at finite μB using lattice studies of the SO(2Nc) theory.",

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AB - We point out that SO(2Nc) gauge theory with Nf fundamental Dirac fermions does not have a sign problem at finite baryon number chemical potential μB. One can thus use lattice Monte Carlo simulations to study this theory at finite density. The absence of a sign problem in the SO(2Nc) theory is particularly interesting because a wide class of observables in the SO(2Nc) theory coincide with observables in QCD in the large Nc limit, as we show using the technique of large Nc orbifold equivalence. We argue that the orbifold equivalence between the two theories continues to hold at finite μB provided one adds appropriate deformation terms to the SO(2Nc) theory. This opens up the prospect of learning about QCD at finite μB using lattice studies of the SO(2Nc) theory.

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Orbifold equivalence and the sign problem at finite Baryon density

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