Pressure-induced two-step spin crossover in double-layered elastic model

We study the two-step spin crossover in a double-layered elastic model based on transition metal complexes each taking high spin (HS) and low spin (LS) states. Here, only the simplest elastic interactions between adjacent molecules are considered and the system is exposed to the external pressure wi...

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Veröffentlicht in:	arXiv.org 2017-11
Hauptverfasser:	Taniguchi, Daisuke, Okabayashi, Jun, Hotta, Chisa
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Coordination compounds Crossovers Enthalpy External pressure Mathematical models Monte Carlo simulation Organic chemistry Physics - Materials Science Pressure effects Transition metal compounds
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description	We study the two-step spin crossover in a double-layered elastic model based on transition metal complexes each taking high spin (HS) and low spin (LS) states. Here, only the simplest elastic interactions between adjacent molecules are considered and the system is exposed to the external pressure within the framework of $NPT$-Monte Carlo method. As a certain amount of pressure is applied, the first order thermal transition between uniform HS and LS phases transforms to a two-step transition with an emergent intermediate spin (IS) phase, where the HS and LS molecules are paired face to face between layers and form diagonally striped clusters within the layer. The difference in the size of HS and LS molecules is reflected both in the elastic interactions and in the enthalpy, and the IS phase could gain the latter over the loss of the former by significantly reducing its volume. The present pressure effect is interpreted to the chemical one in double-layered transition metal materials, which actually reveals a variety of multistep spin crossover transitions relevant to our numerical result.
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Here, only the simplest elastic interactions between adjacent molecules are considered and the system is exposed to the external pressure within the framework of $NPT$-Monte Carlo method. As a certain amount of pressure is applied, the first order thermal transition between uniform HS and LS phases transforms to a two-step transition with an emergent intermediate spin (IS) phase, where the HS and LS molecules are paired face to face between layers and form diagonally striped clusters within the layer. The difference in the size of HS and LS molecules is reflected both in the elastic interactions and in the enthalpy, and the IS phase could gain the latter over the loss of the former by significantly reducing its volume. 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subjects	Computer simulation Coordination compounds Crossovers Enthalpy External pressure Mathematical models Monte Carlo simulation Organic chemistry Physics - Materials Science Pressure effects Transition metal compounds
title	Pressure-induced two-step spin crossover in double-layered elastic model
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