Self-Energy approximation for the running coupling constant in thermal ϕ 4 theory using Imaginary Time Formalism

K. Arjun; A. M. Vinodkumar; Vishnu Mayya Bannur; Munshi G. Mustafa

doi:10.1007/jhep04(2025)178

Journal of High Energy Physics (Apr 2025)

Self-Energy approximation for the running coupling constant in thermal ϕ 4 theory using Imaginary Time Formalism

K. Arjun,
A. M. Vinodkumar,
Vishnu Mayya Bannur,
Munshi G. Mustafa

Affiliations

K. Arjun: Srinivasa Ramanujan Institute For Basic Sciences
A. M. Vinodkumar: Department of Physics, University of Calicut
Vishnu Mayya Bannur: Department of Physics, University of Calicut
Munshi G. Mustafa: Department of Physics, IIT Bombay

DOI: https://doi.org/10.1007/jhep04(2025)178
Journal volume & issue: Vol. 2025, no. 4
pp. 1 – 33

Abstract

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Abstract We investigate the temperature dependence of the mass scale, running coupling constant, and running mass in thermal ϕ 4 theory using the Imaginary Time Formalism (ITF). Employing dimensional regularization and the minimal subtraction scheme, we compute the self-energy up to two-loop order. We introduce a novel Self-Energy Approximation (SEA), which equates the thermal and non-thermal self-energies in the zero external momentum limit. This approximation, combined with the renormalization group equation, imposes constraints that naturally lead to a temperature-dependent mass scale, μ(T), ensuring consistent behavior of the running coupling constant and running mass at finite temperatures. Using these results, the free energy density is evaluated at two-loop order and compared with the quasiparticle model.

Published in Journal of High Energy Physics

ISSN: 1029-8479 (Online)
Publisher: SpringerOpen
Country of publisher: Germany
LCC subjects: Science: Physics: Nuclear and particle physics. Atomic energy. Radioactivity
Website: http://www.springer.com/physics/particle+and+nuclear+physics/journal/13130

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