Supersymmetry and trace formulas. Part I. Compact Lie groups

Changha Choi; Leon A. Takhtajan

doi:10.1007/JHEP06(2024)026

Supersymmetry and trace formulas. Part I. Compact Lie groups

Changha Choi
, Leon A. Takhtajan

Mathematics

Stony Brook University

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

2 Scopus citations

Abstract

In the context of supersymmetric quantum mechanics we formulate new supersymmetric localization principle, with application to trace formulas for a full thermal partition function. Unlike the standard localization principle, this new principle allows to compute the supertrace of non-supersymmetric observables, and is based on the existence of fermionic zero modes. We describe corresponding new invariant supersymmetric deformations of the path integral; they differ from the standard deformations arising from the circle action and require higher derivatives terms. Consequently, we prove that the path integral localizes to periodic orbits and not only on constant ones. We illustrate the principle by deriving bosonic trace formulas on compact Lie groups, including classical Jacobi inversion formula.

Original language	English
Article number	26
Journal	Journal of High Energy Physics
Volume	2024
Issue number	6
DOIs	https://doi.org/10.1007/JHEP06(2024)026
State	Published - Jun 2024

Keywords

Differential and Algebraic Geometry
Field Theories in Lower Dimensions
Sigma Models

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10.1007/JHEP06(2024)026

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title = "Supersymmetry and trace formulas. Part I. Compact Lie groups",

abstract = "In the context of supersymmetric quantum mechanics we formulate new supersymmetric localization principle, with application to trace formulas for a full thermal partition function. Unlike the standard localization principle, this new principle allows to compute the supertrace of non-supersymmetric observables, and is based on the existence of fermionic zero modes. We describe corresponding new invariant supersymmetric deformations of the path integral; they differ from the standard deformations arising from the circle action and require higher derivatives terms. Consequently, we prove that the path integral localizes to periodic orbits and not only on constant ones. We illustrate the principle by deriving bosonic trace formulas on compact Lie groups, including classical Jacobi inversion formula.",

keywords = "Differential and Algebraic Geometry, Field Theories in Lower Dimensions, Sigma Models",

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AU - Choi, Changha

AU - Takhtajan, Leon A.

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PY - 2024/6

Y1 - 2024/6

N2 - In the context of supersymmetric quantum mechanics we formulate new supersymmetric localization principle, with application to trace formulas for a full thermal partition function. Unlike the standard localization principle, this new principle allows to compute the supertrace of non-supersymmetric observables, and is based on the existence of fermionic zero modes. We describe corresponding new invariant supersymmetric deformations of the path integral; they differ from the standard deformations arising from the circle action and require higher derivatives terms. Consequently, we prove that the path integral localizes to periodic orbits and not only on constant ones. We illustrate the principle by deriving bosonic trace formulas on compact Lie groups, including classical Jacobi inversion formula.

AB - In the context of supersymmetric quantum mechanics we formulate new supersymmetric localization principle, with application to trace formulas for a full thermal partition function. Unlike the standard localization principle, this new principle allows to compute the supertrace of non-supersymmetric observables, and is based on the existence of fermionic zero modes. We describe corresponding new invariant supersymmetric deformations of the path integral; they differ from the standard deformations arising from the circle action and require higher derivatives terms. Consequently, we prove that the path integral localizes to periodic orbits and not only on constant ones. We illustrate the principle by deriving bosonic trace formulas on compact Lie groups, including classical Jacobi inversion formula.

KW - Differential and Algebraic Geometry

KW - Field Theories in Lower Dimensions

KW - Sigma Models

UR - https://www.scopus.com/pages/publications/85195507348

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DO - 10.1007/JHEP06(2024)026

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SN - 1126-6708

VL - 2024

JO - Journal of High Energy Physics

JF - Journal of High Energy Physics

IS - 6

M1 - 26

ER -

Supersymmetry and trace formulas. Part I. Compact Lie groups

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