Optimizing the Magnetocaloric Effect in Ni–Mn–Sn by Substitution: A First-Principles Study

Author

Grunebohm, Anna ; Comtesse, Denis ; Hucht, Alfred ; Gruner, Markus E. ; Maslovskaya, Anna ; Entel, Peter

Author_Institution

Dept. of Phys., Univ. of Duisburg-Essen, Duisburg, Germany

Volume

50

Issue

11

fYear

2014

fDate

Nov. 2014

Firstpage

1

Lastpage

4

Abstract

We optimize the magnetic and structural properties of Ni(Co,Cu)MnSn Heusler alloys for the magnetocaloric effect (MCE) by means of density functional theory combined with Monte Carlo simulations of a classical Heisenberg model. NiMnSn alloys show a drop of magnetization at the martensitic phase transition, which leads to the inverse MCE. We find either disordered or frustrated magnetic configurations directly below the martensitic transition temperature. However, the jump of magnetization at the magnetostructural transition is small as the austenite is in a ferrimagnetic state and not fully magnetized. For Co and Cu substitution, the structural phase transition temperature shifts to lower temperatures. In particular, Co substitution is promising, as the magnetization of the austenite increases by additional ferromagnetic interactions, which enhances the jump of magnetization.

Keywords

Heisenberg model; Monte Carlo methods; ab initio calculations; cobalt alloys; copper alloys; crystal structure; density functional theory; ferrimagnetic materials; ferromagnetic materials; frustration; magnetic transition temperature; magnetisation; magnetocaloric effects; manganese alloys; martensitic transformations; nickel alloys; tin alloys; Heusler alloys; Monte Carlo simulations; Ni(CoCu)MnSn; classical Heisenberg model; density functional theory; disordered magnetic configurations; ferrimagnetic state; ferromagnetic interactions; first-principles calculation; frustrated magnetic configurations; magnetic properties; magnetization; magnetocaloric effect; magnetostructural transition; martensitic phase transition; martensitic transition temperature; structural phase transition temperature; structural properties; Frequency modulation; Magnetic properties; Magnetization; Manganese; Temperature; Tin; Ab initio investigations; ferrimagnetic materials; magnetic properties; magnetocaloric effect (MCE);

fLanguage

English

Journal_Title

Magnetics, IEEE Transactions on

Publisher

ieee

ISSN

0018-9464

Type

jour

DOI

10.1109/TMAG.2014.2330845

Filename

6971662