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Bibliographic Details
Main Authors: Harnett, D., Li, Siyuan, Steele, T. G.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.05258
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author Harnett, D.
Li, Siyuan
Steele, T. G.
author_facet Harnett, D.
Li, Siyuan
Steele, T. G.
contents Finite-temperature quantum field theory provides the foundation for many important phenomena in the Standard Model and extensions, including phase transitions, baryogenesis, and gravitational waves. Methods are developed to enable application of pySecDec (a Python-language-based package designed for numerical calculation of dimensionally-regulated loop integrals) to numerically evaluate finite-temperature loop integrals in the imaginary time (Matsubara) formalism. These methods consist of two main elements: an inverse Wick rotation that converts a finite-temperature loop integral into a form applicable to pySecDec, and asymptotic techniques to regulate and accelerate convergence of the Matsubara frequency summations. Numerical pySecDec evaluation of finite-temperature, two-point and three-point, one-loop topologies for scalar fields is used to illustrate and validate these new methodologies. Advantages of these finite-temperature pySecDec numerical methods are illustrated by the inclusion of multiple mass and external momentum scales.
format Preprint
id arxiv_https___arxiv_org_abs_2401_05258
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Numerically Computing Finite Temperature Loop Integrals using pySecDec
Harnett, D.
Li, Siyuan
Steele, T. G.
High Energy Physics - Phenomenology
High Energy Physics - Theory
Finite-temperature quantum field theory provides the foundation for many important phenomena in the Standard Model and extensions, including phase transitions, baryogenesis, and gravitational waves. Methods are developed to enable application of pySecDec (a Python-language-based package designed for numerical calculation of dimensionally-regulated loop integrals) to numerically evaluate finite-temperature loop integrals in the imaginary time (Matsubara) formalism. These methods consist of two main elements: an inverse Wick rotation that converts a finite-temperature loop integral into a form applicable to pySecDec, and asymptotic techniques to regulate and accelerate convergence of the Matsubara frequency summations. Numerical pySecDec evaluation of finite-temperature, two-point and three-point, one-loop topologies for scalar fields is used to illustrate and validate these new methodologies. Advantages of these finite-temperature pySecDec numerical methods are illustrated by the inclusion of multiple mass and external momentum scales.
title Numerically Computing Finite Temperature Loop Integrals using pySecDec
topic High Energy Physics - Phenomenology
High Energy Physics - Theory
url https://arxiv.org/abs/2401.05258