Landau theory of barocaloric plastic crystals

IF 7 3区材料科学 Q1 ENERGY & FUELS

Journal of Physics-Energy Pub Date : 2024-06-19 DOI:10.1088/2515-7655/ad4590

R Marín-Delgado, X Moya and G G Guzmán-Verri

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Abstract

We present a minimal Landau theory of plastic-to-crystal phase transitions in which the key components are a multipole-moment order parameter that describes the orientational ordering of the constituent molecules, coupling between such order parameter and elastic strains, and thermal expansion. We illustrate the theory with the simplest non-trivial model in which the orientational ordering is described by a quadrupole moment, and use such model to calculate barocaloric effects in plastic crystals that are driven by hydrostatic pressure. The model captures characteristic features of plastic-to-crystal phase transitions, namely large changes in volume and entropy at the transition, as well as the linear dependence of the transition temperature with pressure. We identify temperature regions in the barocaloric response associated with the individual plastic and crystal phases, and those involving the phase transition. Our model is in overall agreement with previous experiments in powdered samples of fullerite C60, and predicts peak isothermal entropy changes of and peak adiabatic temperature changes of under GPa at K in fullerite single crystals.

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条状塑性晶体的朗道理论

我们提出了塑性到晶体相变的最小朗道理论，其中的关键部分是描述组成分子取向有序性的多极矩有序参数、该有序参数与弹性应变之间的耦合以及热膨胀。我们用最简单的非三维模型（其中取向有序由四极矩描述）来说明该理论，并使用该模型来计算由静水压力驱动的塑性晶体中的巴焦效应。该模型捕捉到了塑性晶体到晶体相变的特征，即转变时体积和熵的巨大变化，以及转变温度与压力的线性关系。我们确定了与各个塑性相和晶体相相关的巴氏反应温度区域，以及涉及相变的温度区域。我们的模型与之前在富勒石 C60 粉末样品中进行的实验基本一致，并预测富勒石单晶在 K 时的等温熵变化峰值和绝热温度变化峰值在 GPa 以下。

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来源期刊

Journal of Physics-Energy Multiple-

CiteScore

10.90

自引率

1.40%

发文量

期刊介绍： The Journal of Physics-Energy is an interdisciplinary and fully open-access publication dedicated to setting the agenda for the identification and dissemination of the most exciting and significant advancements in all realms of energy-related research. Committed to the principles of open science, JPhys Energy is designed to maximize the exchange of knowledge between both established and emerging communities, thereby fostering a collaborative and inclusive environment for the advancement of energy research.