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Main Authors: López-Picón, J. L., Escamilla-Herrera, L. F., Gil-Villegas, Alejandro, Torres-Arenas, José
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.08690
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author López-Picón, J. L.
Escamilla-Herrera, L. F.
Gil-Villegas, Alejandro
Torres-Arenas, José
author_facet López-Picón, J. L.
Escamilla-Herrera, L. F.
Gil-Villegas, Alejandro
Torres-Arenas, José
contents We investigate several aspects of the thermodynamic geometry for a quantum fluid with square-well interactions using a third-order perturbation theory framework based on the path-integral-necklace analogy. A comparison is made between the thermodynamic and geometric properties of the quantum fluid and its classical counterpart for the interaction ranges $λ^{*}= 1.3$, 1.5, and 1.7. In particular, we analyze the scalar curvature behavior, criticality, and the corresponding Widom lines derived from curvature and several thermodynamic response functions. Quantum effects are shown to smooth supercritical anomalies of the scalar curvature and to shift its extrema for short-range interactions, while leaving the critical exponents of both the curvature and its heat capacity consistent with mean-field predictions. Widom lines associated with temperature-dependent response functions and with the curvature scalar exhibit pronounced classical-quantum differences for short interaction ranges; in contrast, those derived from the isothermal compressibility exhibit only minor variations. Overall, these results highlight the sensitivity of geometric information of thermodynamic systems due to quantum effects and the crucial role of the interaction range in shaping supercritical thermodynamic behavior.
format Preprint
id arxiv_https___arxiv_org_abs_2603_08690
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle The quantum square-well fluid: a thermodynamic geometric view
López-Picón, J. L.
Escamilla-Herrera, L. F.
Gil-Villegas, Alejandro
Torres-Arenas, José
Statistical Mechanics
Quantum Gases
We investigate several aspects of the thermodynamic geometry for a quantum fluid with square-well interactions using a third-order perturbation theory framework based on the path-integral-necklace analogy. A comparison is made between the thermodynamic and geometric properties of the quantum fluid and its classical counterpart for the interaction ranges $λ^{*}= 1.3$, 1.5, and 1.7. In particular, we analyze the scalar curvature behavior, criticality, and the corresponding Widom lines derived from curvature and several thermodynamic response functions. Quantum effects are shown to smooth supercritical anomalies of the scalar curvature and to shift its extrema for short-range interactions, while leaving the critical exponents of both the curvature and its heat capacity consistent with mean-field predictions. Widom lines associated with temperature-dependent response functions and with the curvature scalar exhibit pronounced classical-quantum differences for short interaction ranges; in contrast, those derived from the isothermal compressibility exhibit only minor variations. Overall, these results highlight the sensitivity of geometric information of thermodynamic systems due to quantum effects and the crucial role of the interaction range in shaping supercritical thermodynamic behavior.
title The quantum square-well fluid: a thermodynamic geometric view
topic Statistical Mechanics
Quantum Gases
url https://arxiv.org/abs/2603.08690