Engineering the magnetocaloric properties of PrVO3 epitaxial oxide thin films by strain effects

Combining multiple degrees of freedom in strongly correlated materials such as transition-metal oxides would lead to fascinating magnetic and magnetocaloric features. Herein, the strain effects are used to markedly tailor the magnetic and magnetocaloric properties of PrVO3 thin films. The selection...

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Bibliographic Details
Published in:Applied physics letters 2020-08, Vol.117 (7)
Main Authors: Bouhani, H., Endichi, A., Kumar, D., Copie, O., Zaari, H., David, A., Fouchet, A., Prellier, W., Mounkachi, O., Balli, M., Benyoussef, A., El Kenz, A., Mangin, S.
Format: Article
Language:English
Subjects:
Applied physics
Coercivity
Cryogenic temperature
Degrees of freedom
Magnetic fields
Magnetic moments
Magnetic properties
Magnetism
Substrates
Thin films
Transition metal oxides
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Summary:Combining multiple degrees of freedom in strongly correlated materials such as transition-metal oxides would lead to fascinating magnetic and magnetocaloric features. Herein, the strain effects are used to markedly tailor the magnetic and magnetocaloric properties of PrVO3 thin films. The selection of an appropriate thickness and substrate enables us to dramatically decrease the coercive magnetic field from 2.4 T previously observed in sintered PVO3 bulk to 0.05 T for compressive thin films making from the PrVO3 compound a nearly soft magnet. This is associated with a marked enhancement of the magnetic moment and the magnetocaloric effect that reaches unusual maximum values of roughly 4.86 μB and 56.8 J/kg K with the magnetic field change of 6 T applied in the sample plane in the cryogenic temperature range (3 K), respectively. This work strongly suggests that taking advantage of different degrees of freedom and the exploitation of multiple instabilities in a nanoscale regime is a promising strategy for unveiling unexpected phases accompanied by a large magnetocaloric effect in oxides.
ISSN:0003-6951
1077-3118
DOI:10.1063/5.0021031