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Autori principali: Bian, Ligong, Wang, Hongxin, Xiao, Yang, Yang, Ji-Chong, Yang, Jin Min, Zhang, Yang
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.10667
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author Bian, Ligong
Wang, Hongxin
Xiao, Yang
Yang, Ji-Chong
Yang, Jin Min
Zhang, Yang
author_facet Bian, Ligong
Wang, Hongxin
Xiao, Yang
Yang, Ji-Chong
Yang, Jin Min
Zhang, Yang
contents The computation of bounce action in a phase transition involves solving partial differential equations, inherently introducing non-negligible numerical uncertainty. Deriving characteristic temperatures and properties of this transition necessitates both differentiation and integration of the action, thereby exacerbating the uncertainty. In this work, we fit the action curve as a function of temperature to mitigate the uncertainties inherent in the calculation of the phase transition parameters. We find that, after extracting a factor, the sixth-order polynomial yields an excellent fit for the action in the high temperature approximated potential. In a realistic model, the singlet extension of the Standard Model, this method performs satisfactorily across most of the parameter space after trimming the fitting data. This approach not only enhances the accuracy of phase transition calculations but also systematically reduces computation time and facilitates error estimation, particularly in models involving multiple scalar fields. Furthermore, we discussed the possible of using multiple neural networks to predict the action curve from model parameters.
format Preprint
id arxiv_https___arxiv_org_abs_2510_10667
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhancing Phase Transition Calculations with Fitting and Neural Network
Bian, Ligong
Wang, Hongxin
Xiao, Yang
Yang, Ji-Chong
Yang, Jin Min
Zhang, Yang
High Energy Physics - Phenomenology
The computation of bounce action in a phase transition involves solving partial differential equations, inherently introducing non-negligible numerical uncertainty. Deriving characteristic temperatures and properties of this transition necessitates both differentiation and integration of the action, thereby exacerbating the uncertainty. In this work, we fit the action curve as a function of temperature to mitigate the uncertainties inherent in the calculation of the phase transition parameters. We find that, after extracting a factor, the sixth-order polynomial yields an excellent fit for the action in the high temperature approximated potential. In a realistic model, the singlet extension of the Standard Model, this method performs satisfactorily across most of the parameter space after trimming the fitting data. This approach not only enhances the accuracy of phase transition calculations but also systematically reduces computation time and facilitates error estimation, particularly in models involving multiple scalar fields. Furthermore, we discussed the possible of using multiple neural networks to predict the action curve from model parameters.
title Enhancing Phase Transition Calculations with Fitting and Neural Network
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2510.10667