2017
DOI: 10.1002/pssb.201700278
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Hysteresis and Phase Transition Kinetics in Magnetocaloric Materials

Abstract: In the present paper, we review the recent research on the physics of magnetocaloric materials aiming to define a coherent theoretical framework in which hysteresis and kinetic effects can be appropriately discussed and interpreted in relation to intrinsic and extrinsic factors. We dedicate our efforts to introduce a thermodynamic description of the material, including the out-of-equilibrium aspects which are necessary to understand hysteresis, heat flux avalanches and thermal relaxation effects. In particular… Show more

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Cited by 15 publications
(16 citation statements)
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“…Our observations in the preceding paragraph indicate that the discrepancy between our work and previous phenomenological descriptions 42,43,50 regarding the counteracting role of ∆S vib might be traced back to the modeling of the coupling between magnetism and lattice degrees of freedom. In the spirit of the Bean-Rodbell model it is often assumed that the molecular field, which derives from the magnetic exchange interactions, depends mainly on the interatomic spacing, as for instance predicted by the Bethe-Slater curve.…”
Section: Resultscontrasting
confidence: 80%
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“…Our observations in the preceding paragraph indicate that the discrepancy between our work and previous phenomenological descriptions 42,43,50 regarding the counteracting role of ∆S vib might be traced back to the modeling of the coupling between magnetism and lattice degrees of freedom. In the spirit of the Bean-Rodbell model it is often assumed that the molecular field, which derives from the magnetic exchange interactions, depends mainly on the interatomic spacing, as for instance predicted by the Bethe-Slater curve.…”
Section: Resultscontrasting
confidence: 80%
“…In the spirit of the Bean-Rodbell model it is often assumed that the molecular field, which derives from the magnetic exchange interactions, depends mainly on the interatomic spacing, as for instance predicted by the Bethe-Slater curve. 43 In turn, lattice degrees of freedom depend on the atomic volume as well, which is often modeled in terms of a conventional Grüneisen behavior. Our work shows, however, that in La(Fe,Si) 13 -based compounds a different mechanism based on adiabatic electron-phonon-coupling dominates the magnetoelastic interactions, which derives solely from local changes in the electronic structure, 46 which are by definition not considered in a Bean-Rodbell-type model.…”
Section: Resultsmentioning
confidence: 99%
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“…In general, trueγ is a positive, material‐specific constant, and we thus expect a blue‐shift (increase) of the VDOS for Δ V< 0, which corresponds to a smaller entropy according to Equation (5). Empirical calculations of the MCE of La–Fe–Si combine the conventional Grüneisen law with localized spin models to yield a good agreement with experiments …”
Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning
confidence: 80%
“…Empirical calculations of the MCE of La-Fe-Si combine the conventionalG r üneisen law with localized spin models to yield agood agreementwith experiments. [74,76,77] To obtain more detailed information on the subtle interplay of itinerant magnetism and lattice entropyw ee xamined the VDOS at different temperatures above and below T t . Using temperature-dependent nuclear resonant inelastic Xray scattering (NRIXS) we measured the vibrational part of the entropy S lat .A tp resent,N RIXS measurements of the 57 Fe projected VDOS, g(e), have been performed at the Sector3 beam line at the Advanced Photon Sourcea tA rgonne National Laboratory.B yt uning the incident X-ray around the nuclear resonance of 57 Fe at 14.41 keV with a bandwidth as narrowa s1meV, [78] the 57 Fe-projected VDOS can be extracted from the measured NRIXS spectra.…”
Section: Disentangling the Microscopic Contributions To The Entropy Cmentioning
confidence: 99%