Modeling specific heat and entropy change in La(Fe–Mn–Si)13–H compounds

In this paper we model the magnetocaloric effect of LaFexMnySiz–H1.65 compound (x+y+z=13), a system showing a transition temperature finely tunable around room temperature by Mn substitution. The thermodynamic model takes into account the coupling between magnetism and specific volume as introduced...

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Bibliographic Details
Published in:Journal of magnetism and magnetic materials 2016-02, Vol.400, p.349-355
Main Authors: Piazzi, Marco, Bennati, Cecilia, Curcio, Carmen, Kuepferling, Michaela, Basso, Vittorio
Format: Article
Language:English
Subjects:
Entropy change
Magnetocaloric effect
Magnetoelastic coupling
Mean field theory
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Summary:In this paper we model the magnetocaloric effect of LaFexMnySiz–H1.65 compound (x+y+z=13), a system showing a transition temperature finely tunable around room temperature by Mn substitution. The thermodynamic model takes into account the coupling between magnetism and specific volume as introduced by Bean and Rodbell. We find a good qualitative agreement between experimental and modeled entropy change −Δs(H,T). The main result is that the magnetoelastic coupling drives the phase transition of the system, changing it from second to first order by varying a model parameter η. It is also responsible for a decrease of −Δs at the transition, due to a small lattice contribution to the entropy counteracting the effect of the magnetic one. The role of Mn is reflected exclusively in a decrease of the strength of the exchange interaction, while the value of the coefficient β, responsible for the coupling between volume and exchange energy, is independent on the Mn content and it appears to be an intrinsic property of the La(Fe–Si)13 structure. •We use a magnetoelastic model to obtain entropy and specific heat in La(Fe,Mn,Si)13–H.•Measured entropy changes are well reproduced by finely tuning the model parameters.•Structural entropy at the transition counteracts the effect of magnetic entropy.•Exchange coupling parameter is shown to depend on Mn content.•Magnetoelastic coupling depends on the La(Fe,Si)13 structure.
ISSN:0304-8853
DOI:10.1016/j.jmmm.2015.07.055