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Autori principali: Valverde-Muñoz, Francisco Javier, Ramírez, Ricardo Guillermo Torres, Trzop, Elzbieta, Bataille, Thierry, Daro, Nathalie, Denux, Dominique, Guionneau, Philippe, Cailleau, Hervé, Chastanet, Guillaume, Guennic, Boris Le, Collet, Eric
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2411.11418
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author Valverde-Muñoz, Francisco Javier
Ramírez, Ricardo Guillermo Torres
Trzop, Elzbieta
Bataille, Thierry
Daro, Nathalie
Denux, Dominique
Guionneau, Philippe
Cailleau, Hervé
Chastanet, Guillaume
Guennic, Boris Le
Collet, Eric
author_facet Valverde-Muñoz, Francisco Javier
Ramírez, Ricardo Guillermo Torres
Trzop, Elzbieta
Bataille, Thierry
Daro, Nathalie
Denux, Dominique
Guionneau, Philippe
Cailleau, Hervé
Chastanet, Guillaume
Guennic, Boris Le
Collet, Eric
contents Symmetry-breaking is pivotal for controlling ferroelectric, ferroelastic and/or ferromagnetic functions of materials, which enables applications in sensors, memories, transducers or actuators. Commonly, ferroic phases emerge from descending symmetry-breaking, as the laws of thermodynamics dictate that the ordered low entropy phases form at low temperature, which limits practical applications of many materials at room temperature. Rare examples of ascending symmetry-breakings have been observed, but the driving force remains often unclear. Here, we report on a ferroelastic symmetry-breaking occurring at high temperature in a spin-crossover material, studied by magnetic, DSC and X-ray diffraction measurements. Our DFT calculations and our model, based on the Landau theory of phase transitions, explain how the cooperative thermal switching of molecular spin state drives a ferroelastic symmetry breaking at high temperature, through a coupled Jahn-Teller distortion. Ferroelastic materials have rich properties, with important applications in memory, multifunctional and novel controllable devices. The electronic bistability in soft functional materials represents an important source of entropy gain, capable of overcoming the cost of symmetry-breaking entropy, which opens up new perspectives for stabilizing high-temperature and low-symmetry ferroic functions of advanced materials
format Preprint
id arxiv_https___arxiv_org_abs_2411_11418
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Stabilizing low symmetry-based functions of materials at room temperature through isosymmetric electronic bistability
Valverde-Muñoz, Francisco Javier
Ramírez, Ricardo Guillermo Torres
Trzop, Elzbieta
Bataille, Thierry
Daro, Nathalie
Denux, Dominique
Guionneau, Philippe
Cailleau, Hervé
Chastanet, Guillaume
Guennic, Boris Le
Collet, Eric
Materials Science
Symmetry-breaking is pivotal for controlling ferroelectric, ferroelastic and/or ferromagnetic functions of materials, which enables applications in sensors, memories, transducers or actuators. Commonly, ferroic phases emerge from descending symmetry-breaking, as the laws of thermodynamics dictate that the ordered low entropy phases form at low temperature, which limits practical applications of many materials at room temperature. Rare examples of ascending symmetry-breakings have been observed, but the driving force remains often unclear. Here, we report on a ferroelastic symmetry-breaking occurring at high temperature in a spin-crossover material, studied by magnetic, DSC and X-ray diffraction measurements. Our DFT calculations and our model, based on the Landau theory of phase transitions, explain how the cooperative thermal switching of molecular spin state drives a ferroelastic symmetry breaking at high temperature, through a coupled Jahn-Teller distortion. Ferroelastic materials have rich properties, with important applications in memory, multifunctional and novel controllable devices. The electronic bistability in soft functional materials represents an important source of entropy gain, capable of overcoming the cost of symmetry-breaking entropy, which opens up new perspectives for stabilizing high-temperature and low-symmetry ferroic functions of advanced materials
title Stabilizing low symmetry-based functions of materials at room temperature through isosymmetric electronic bistability
topic Materials Science
url https://arxiv.org/abs/2411.11418