The gradient flow of the Dirac spectrum

Alexander S. Christensen; K. Splittorff; J. J.M. Verbaarschot

doi:10.1007/JHEP11(2014)113

The gradient flow of the Dirac spectrum

Alexander S. Christensen
, K. Splittorff
, J. J.M. Verbaarschot

Physics and Astronomy

University of Copenhagen

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

We construct chiral perturbation theory for the gradient flow of the microscopic Dirac eigenvalues and compute the density of and correlations between the microscopic eigenvalues at zero and non-zero flow time. The results show that the repulsion of the microscopic Dirac eigenvalues from the dynamical quark mass decreases with increasing gradient flow time. Furthermore, the flow of the spectral resolvent is compared to the flow of the chiral condensate obtained from a fermionic gradient flow.

Original language	English
Article number	113
Journal	Journal of High Energy Physics
Volume	2014
Issue number	11
DOIs	https://doi.org/10.1007/JHEP11(2014)113
State	Published - Nov 2014

Keywords

Effective field theories
Lattice Quantum Field Theory
Spontaneous Symmetry Breaking

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10.1007/JHEP11(2014)113

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title = "The gradient flow of the Dirac spectrum",

abstract = "We construct chiral perturbation theory for the gradient flow of the microscopic Dirac eigenvalues and compute the density of and correlations between the microscopic eigenvalues at zero and non-zero flow time. The results show that the repulsion of the microscopic Dirac eigenvalues from the dynamical quark mass decreases with increasing gradient flow time. Furthermore, the flow of the spectral resolvent is compared to the flow of the chiral condensate obtained from a fermionic gradient flow.",

keywords = "Effective field theories, Lattice Quantum Field Theory, Spontaneous Symmetry Breaking",

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AU - Splittorff, K.

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N2 - We construct chiral perturbation theory for the gradient flow of the microscopic Dirac eigenvalues and compute the density of and correlations between the microscopic eigenvalues at zero and non-zero flow time. The results show that the repulsion of the microscopic Dirac eigenvalues from the dynamical quark mass decreases with increasing gradient flow time. Furthermore, the flow of the spectral resolvent is compared to the flow of the chiral condensate obtained from a fermionic gradient flow.

AB - We construct chiral perturbation theory for the gradient flow of the microscopic Dirac eigenvalues and compute the density of and correlations between the microscopic eigenvalues at zero and non-zero flow time. The results show that the repulsion of the microscopic Dirac eigenvalues from the dynamical quark mass decreases with increasing gradient flow time. Furthermore, the flow of the spectral resolvent is compared to the flow of the chiral condensate obtained from a fermionic gradient flow.

KW - Effective field theories

KW - Lattice Quantum Field Theory

KW - Spontaneous Symmetry Breaking

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DO - 10.1007/JHEP11(2014)113

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JF - Journal of High Energy Physics

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The gradient flow of the Dirac spectrum

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Keywords

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