Nonperturbative thermodynamic extrinsic curvature of the anyon gas

Thermodynamic extrinsic curvature is a new mathematical tool in thermodynamic geometry. By using the thermodynamic extrinsic curvature, one may obtain a more complete geometric representation of the critical phenomena and thermodynamics. We introduce nonperturbative thermodynamic extrinsic curvature...

Full description

Saved in:
Bibliographic Details
Published in:arXiv.org 2024-05
Main Authors: Mahnaz Tavakoli Kachi, Mirza, Behrouz, Fatemeh Sadat Hashemi
Format: Article
Language:English
Subjects:
Critical phenomena
Critical point
Curvature
Ising model
Scaling
Thermodynamics
Three dimensional models
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Thermodynamic extrinsic curvature is a new mathematical tool in thermodynamic geometry. By using the thermodynamic extrinsic curvature, one may obtain a more complete geometric representation of the critical phenomena and thermodynamics. We introduce nonperturbative thermodynamic extrinsic curvature of an ideal two dimensional gas of anyons. Using extrinsic curvature, we find new fixed points in nonperturbative thermodynamics of the anyon gas that particles behave as semions. Here, we investigate the critical behavior of thermodynamic extrinsic curvature of two-dimensional Kagome Ising model near the critical point \( \beta_{c} =({{k_{B} T_{c}}})^{-1}\) in a constant magnetic field and show that it behaves as \( \left| {\beta- \beta_{c} } \right|^{\alpha} \) with \( \alpha=0 \), where \( \alpha \) denotes the critical exponent of the specific heat. Then, we consider the three dimensional spherical model and show that the scaling behavior is \( \left| {\beta- \beta_{c} } \right|^{\alpha} \) , where \( \alpha =-1 \). Finally, using a general argument, we show that extrinsic curvature \( K \) have two different scaling behaviors for positive and negative \( \alpha \). For \(\alpha> 0\), our results indicate that \( K \sim \left|{\beta- \beta_{c} } \right|^{{\frac{1}{2}} (\alpha-2)} \). However, for \( \alpha
ISSN:2331-8422
DOI:10.48550/arxiv.2405.04013