2009
DOI: 10.1063/1.3130229
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Entropy change and effect of magnetic field on martensitic transformation in a metamagnetic Ni–Co–Mn–In shape memory alloy

Abstract: We studied the entropy change and the shift of the martensitic transformation temperatures with magnetic field in samples of a polycrystalline Ni–Co–Mn–In alloy having different degrees of long-range atomic order due to different heat treatments. We found, for the samples of the same composition, strong variations of the entropy change with the degree of atomic order, mediated by the difference between the Curie and martensitic transformation temperatures. Calculations of the field-induced shift of the transfo… Show more

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Cited by 130 publications
(81 citation statements)
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“…Reports of a similar tendency of ΔS can be found in other ternary NiMn-In alloys [53,54]. The decrease of ΔS below T C,P by direct measurements can also be found in Sb-doped [55] and Co-doped [56] quaternary systems, as well as in the Ni 50−x Co x Mn 50−y Al y system [57]. This common tendency is considered to be the thermodynamic cause of the "thermal transformation arrest phenomenon" [58,59], where the martensitic transformation is interrupted at a certain temperature during the cooling process.…”
Section: Entropy Change During Martensitic Transformationsupporting
confidence: 56%
“…Reports of a similar tendency of ΔS can be found in other ternary NiMn-In alloys [53,54]. The decrease of ΔS below T C,P by direct measurements can also be found in Sb-doped [55] and Co-doped [56] quaternary systems, as well as in the Ni 50−x Co x Mn 50−y Al y system [57]. This common tendency is considered to be the thermodynamic cause of the "thermal transformation arrest phenomenon" [58,59], where the martensitic transformation is interrupted at a certain temperature during the cooling process.…”
Section: Entropy Change During Martensitic Transformationsupporting
confidence: 56%
“…Comparable results are known in Ni-rich Ni-and Mn-based Heusler alloys [19,20]. A similar feature has been found for Ni-Co-Mn-In alloys and is attributed to the modification of the atomic sites (order-disorder), the Mn-Mn distances and the Mn-Mn exchange coupling [47][48][49][50]. Additionally, based on this, the Fermi surface and the Brillouin zone boundary can be affected [50][51][52][53].…”
Section: Magnetic Propertiessupporting
confidence: 55%
“…T -Ap), the greater the magnetic contribution to the entropy change, hence the overall transformation entropy diminishes, as it has been observed for many different metamagnetic alloys [14,15,[24][25][26]. Owing to the thermal hysteresis of the MT, ( ⏐, which can only be fulfilled if "paramagnetic" martensite has higher degree of magnetic order than paramagnetic austenite [14].…”
Section: Contributions To the Entropy Change At The Magnetostructuralmentioning
confidence: 96%
“…The main contributions to the measured transformation entropy changes, as commonly accepted, include structural and magnetic contributions [14,26]: …”
Section: Contributions To the Entropy Change At The Magnetostructuralmentioning
confidence: 99%
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