Magnetocaloric effect in Fe2 P: Magnetic and phonon degrees of freedom
Journal article, 2019

Devices based on magnetocaloric materials provide great hope for environmentally friendly and energy efficient cooling that does not rely on the use of harmful gasses. Fe2P based compounds are alloys that have shown great potential for magnetocaloric devices. The magnetic behavior in Fe2P is characterized by a strong magnetocaloric effect that coexists with a first-order magnetic transition (FOMT). Neutron diffraction and inelastic scattering, Mossbauer spectroscopy, and first-principles calculations have been used to determine the structural and magnetic state of Fe2P around the FOMT. The results reveal that ferromagnetic moments in the ordered phase are perturbed at the FOMT such that the moments cant away from the principle direction within a small temperature region. The acoustic-phonon modes reveal a temperature-dependent nonzero energy gap in the magnetically ordered phase that falls to zero at the FOMT. The interplay between the FOMT and the phonon energy gap indicates hybridization between magnetic modes strongly affected by spin-orbit coupling and phonon modes leading to magnon-phonon quasiparticles that drive the magnetocaloric effect.

Author

J. Cedervall

Uppsala University

Mikael Andersson

Chalmers, Chemistry and Chemical Engineering, Energy and Material

Uppsala University

E. K. Delczeg-Czirjak

Uppsala University

D. Iusan

Uppsala University

M. Pereiro

Uppsala University

P. Roy

Radboud University

T. Ericsson

Uppsala University

L. Haggstrom

Uppsala University

W. Lohstroh

Technical University of Munich

H. Mutka

Institut Laue-Langevin

M. Sahlberg

Uppsala University

P. Nordblad

Uppsala University

P. P. Deen

University of Copenhagen

European Spallation Source (ESS)

Physical Review B

2469-9950 (ISSN) 2469-9969 (eISSN)

Vol. 99 17 174437

Subject Categories

Inorganic Chemistry

Other Physics Topics

Condensed Matter Physics

DOI

10.1103/PhysRevB.99.174437

More information

Latest update

6/15/2023