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High‐Throughput Design of Magnetocaloric Materials for Energy Applications: MM´X alloys

Nuno M. Fortunato, Andreas Taubel, Alberto Marmodoro, Lukas Pfeuffer, Ingo Ophale, Hebert Ebert, Oliver Gutfleisch, Hongbin Zhang

2023Advanced Science24 citationsDOIOpen Access PDF

Abstract

Magnetic refrigeration offers an energy efficient and environmental friendly alternative to conventional vapor-cooling. However, its adoption depends on materials with tailored magnetic and structural properties. Here a high-throughput computational workflow for the design of magnetocaloric materials is introduced. Density functional theory calculations are used to screen potential candidates in the family of MM'X (M/M' = metal, X = main group element) compounds. Out of 274 stable compositions, 46 magnetic compounds are found to stabilize in both an austenite and martensite phase. Following the concept of Curie temperature window, nine compounds are identified as potential candidates with structural transitions, by evaluating and comparing the structural phase transition and magnetic ordering temperatures. Additionally, the use of doping to tailor magnetostructural coupling for both known and newly predicted MM'X compounds is predicted and isostructural substitution as a general approach to engineer magnetocaloric materials is suggested.

Topics & Concepts

Magnetic refrigerationThroughputMaterials scienceProcess engineeringNanotechnologyMetallurgyComputer scienceEngineeringPhysicsMagnetizationOperating systemWirelessQuantum mechanicsMagnetic fieldMagnetic and transport properties of perovskites and related materialsFerroelectric and Piezoelectric MaterialsShape Memory Alloy Transformations
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