Moment evolution across the ferromagnetic phase transition of giant magnetocaloric (Mn, Fe)(2)(P, Si, B) compounds

H. Yibole; F. Guillou; L. Caron; E. Jimenez; F. M. F. de Groot; P. Roy; R. de Groot; N. H. van Dijk; E. Bruck

doi:10.1103/PhysRevB.91.014429

Moment evolution across the ferromagnetic phase transition of giant magnetocaloric (Mn, Fe)(2)(P, Si, B) compounds

H. Yibole^*, F. Guillou, L. Caron, E. Jimenez, F. M. F. de Groot, P. Roy, R. de Groot, N. H. van Dijk, E. Bruck

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

A strong electronic reconstruction resulting in a quenching of the Fe magnetic moments has recently been predicted to be at the origin of the giant magnetocaloric effect displayed by Fe2P-based materials. To verify this scenario, x-raymagnetic circular dichroism experiments have been carried out at the L edges of Mn and Fe for two typical compositions of the (Mn, Fe)(2)(P, Si, B) system. The dichroic absorption spectra of Mn and Fe have been measured in the vicinity of the first-order ferromagnetic transition. The experimental spectra are compared with first-principles calculations and charge-transfer multiplet simulations in order to derive the magnetic moments. Even though signatures of a metamagnetic behavior are observed either as a function of the temperature or the magnetic field, the similarity of the Mn and Fe moment evolution suggests that the quenching of the Fe moment is weaker than previously predicted.

Original language	English
Article number	014429
Number of pages	10
Journal	Physical review. B, Condensed matter and materials physics
Volume	91
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevB.91.014429
Publication status	Published - 23 Jan 2015

Funding

We acknowledge the European Synchrotron Radiation Facility for provision of synchrotron radiation facilities and thank the beamline staff for assistance in using beam line ID08. The authors would like to thank Cinthia Piamonteze and Anne-Christine Uldry for helpful discussions. This work is financially supported by the Foundation for Fundamental Research on Matter (FOM) (The Netherlands) and BASF New Business.

Keywords

X-RAY-ABSORPTION
CIRCULAR-DICHROISM
METAL COMPOUNDS
METAMAGNETIC TRANSITION
1ST-ORDER TRANSITION
NEUTRON-DIFFRACTION
MAGNETIC-STRUCTURE
ENTROPY CHANGE
SUM-RULE
REFRIGERATION

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Yibole, H., Guillou, F., Caron, L., Jimenez, E., de Groot, F. M. F., Roy, P., de Groot, R., van Dijk, N. H., & Bruck, E. (2015). Moment evolution across the ferromagnetic phase transition of giant magnetocaloric (Mn, Fe)(2)(P, Si, B) compounds. Physical review. B, Condensed matter and materials physics, 91(1), Article 014429. https://doi.org/10.1103/PhysRevB.91.014429

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title = "Moment evolution across the ferromagnetic phase transition of giant magnetocaloric (Mn, Fe)(2)(P, Si, B) compounds",

abstract = "A strong electronic reconstruction resulting in a quenching of the Fe magnetic moments has recently been predicted to be at the origin of the giant magnetocaloric effect displayed by Fe2P-based materials. To verify this scenario, x-raymagnetic circular dichroism experiments have been carried out at the L edges of Mn and Fe for two typical compositions of the (Mn, Fe)(2)(P, Si, B) system. The dichroic absorption spectra of Mn and Fe have been measured in the vicinity of the first-order ferromagnetic transition. The experimental spectra are compared with first-principles calculations and charge-transfer multiplet simulations in order to derive the magnetic moments. Even though signatures of a metamagnetic behavior are observed either as a function of the temperature or the magnetic field, the similarity of the Mn and Fe moment evolution suggests that the quenching of the Fe moment is weaker than previously predicted.",

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AU - Yibole, H.

AU - Guillou, F.

AU - Caron, L.

AU - Jimenez, E.

AU - de Groot, F. M. F.

AU - Roy, P.

AU - de Groot, R.

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AB - A strong electronic reconstruction resulting in a quenching of the Fe magnetic moments has recently been predicted to be at the origin of the giant magnetocaloric effect displayed by Fe2P-based materials. To verify this scenario, x-raymagnetic circular dichroism experiments have been carried out at the L edges of Mn and Fe for two typical compositions of the (Mn, Fe)(2)(P, Si, B) system. The dichroic absorption spectra of Mn and Fe have been measured in the vicinity of the first-order ferromagnetic transition. The experimental spectra are compared with first-principles calculations and charge-transfer multiplet simulations in order to derive the magnetic moments. Even though signatures of a metamagnetic behavior are observed either as a function of the temperature or the magnetic field, the similarity of the Mn and Fe moment evolution suggests that the quenching of the Fe moment is weaker than previously predicted.

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KW - METAL COMPOUNDS

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KW - MAGNETIC-STRUCTURE

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ER -

Moment evolution across the ferromagnetic phase transition of giant magnetocaloric (Mn, Fe)(2)(P, Si, B) compounds

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Keywords

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