Martensitic and Magnetic Transformation Behaviors in Heusler-Type NiMnIn and NiCoMnIn Metamagnetic Shape Memory Alloys

Ito, Wataru; Imano, Y.; Kainuma, Ryosuke; Sutou, Yuji; Oikawa, Katsunari; Ishida, K.

doi:10.1007/s11661-007-9094-9

Cited by 277 publications

(147 citation statements)

References 25 publications

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“…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: 92%

“…A C T -TO) has been widely proven for different metamagnetic alloys [14,15,[24][25][26]], a phenomenological model has been recently developed, based on a BraggWilliams approximation, accounting for the magnetic contribution. The model achieves excellent agreement between calculated and experimental ΔS for different composition and atomic order degrees, corroborating the magnetic origin of changes in transformation entropy [23,27].…”

Section: While a Decrease Of δS With Increasing (mentioning

confidence: 99%

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Contributions to the Transformation Entropy Change and Influencing Factors in Metamagnetic Ni-Co-Mn-Ga Shape Memory Alloys

Seguı́¹,

Cesari²

2014

Entropy

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Ni-Co-Mn-Ga ferromagnetic shape memory alloys show metamagnetic transition from ferromagnetic austenite to paramagnetic (or weak-magnetic) martensite for a limited range of Co contents. The temperatures of the structural and magnetic transitions depend strongly on composition and atomic order degree, in such a way that combined composition and thermal treatment allows obtaining martensitic transformation (MT) between any magnetic state of austenite and martensite. The entropy change ΔS measured in the magnetostructural transition comprises a magnetic contribution which depends on the type and degree of magnetic order of the related phases. Consequently, both the magnetization jump across the MT (ΔM) and ΔS are composition and atomic order dependent. Both ΔS and ΔM determine the effect of applied magnetic fields on the MT, hence knowledge and understanding of their behavior can help to approach the best conditions for magnetic field induced MT and related effects. In previous papers, we have reported findings regarding the behavior of the transformation entropy in relation to composition and atomic order in Ni50−xCoxMn25+yGa25−y (x = 3-8, y = 5-7) alloys. In the present paper we will review our recent results, summarizing the key findings and drawing general conclusions regarding the magnetic contribution to ΔS and the effect of different factors on the magnetic and structural properties of these metamagnetic alloys. OPEN ACCESSEntropy 2014, 16 5561

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Section: Contributions To the Entropy Change At The Magnetostructuralmentioning

confidence: 92%

Section: While a Decrease Of δS With Increasing (mentioning

confidence: 99%

Contributions to the Transformation Entropy Change and Influencing Factors in Metamagnetic Ni-Co-Mn-Ga Shape Memory Alloys

Seguı́¹,

Cesari²

2014

Entropy

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show abstract

“…2) Especially, the Co-doped Ni-Mn-In and -Sn quaternary alloys show a drastic change of magnetization by martensitic transformation from a ferromagnetic P phase to a very weakly magnetic M phase. [3][4][5] The martensitic transformation temperatures of these alloys are drastically decreased by the application of a magnetic field, and magnetic field-induced reverse transformation (MFIRT) has been confirmed.…”

Section: Introductionmentioning

confidence: 93%

Shape Memory Response in Ni40Co10Mn33Al17 Polycrystalline Alloy

et al. 2010

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Shape memory response of the polycrystalline Ni 40 Co 10 Mn 33 Al 17 alloy were investigated. In the isobaric thermal cycling experiments, the measured transformation strain levels increased with increasing stress reaching about 3.6% under 200 MPa. The slope of the stress vs. transformation temperature diagram, constructed using the data from these experiments, almost coincided with the predicted one obtained using the Clausius-Clapeyron equation, and experimental entropy data and transformation strain. Perfect pseudoelasticity was observed up to 405 K during compressive straining up to 2.5%.

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“…Table 2. T 0 is the transformation temperature where the parent phase has the same Gibbs energy as that of the product martensite phase and is approximated by (A f + M s )/2 [33][34][35][36]. martenstite (x > 6.5) from austenite (0 < x < 6.5) at room temperature.…”

Section: Thermal Analysismentioning

confidence: 99%

Giant magnetocaloric effect from reverse martensitic transformation in Ni–Mn–Ga–Cu ferromagnetic shape memory alloys

Sarkar

Sarita

Babu

et al. 2016

Journal of Alloys and Compounds

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Abstract:In an effort to produce Giant Magnetocaloric effect (GMCE) near room temperature, in a first ever such study, the austenite transformation temperature (A s ) was fine tuned to Concurrently, ∆SM increases with Cu addition and peaks at 6.5 at. % Cu for which there is a virtual overlap between T C and A s . Maximum Refrigerant Capacity (RCP) of 327.01 J/Kg was also achieved in the heating cycle for 9 T field change at 302.5 K. Corresponding values for the cooling cycle measurements (measured during forward transformation) were 30.4 J/Kg-K and 123.52 J/Kg respectively for the same 6.5 at. % Cu sample and same thermomagnetic conditions.

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Martensitic and Magnetic Transformation Behaviors in Heusler-Type NiMnIn and NiCoMnIn Metamagnetic Shape Memory Alloys

Cited by 277 publications

References 25 publications

Contributions to the Transformation Entropy Change and Influencing Factors in Metamagnetic Ni-Co-Mn-Ga Shape Memory Alloys

Contributions to the Transformation Entropy Change and Influencing Factors in Metamagnetic Ni-Co-Mn-Ga Shape Memory Alloys

Shape Memory Response in Ni<SUB>40</SUB>Co<SUB>10</SUB>Mn<SUB>33</SUB>Al<SUB>17</SUB> Polycrystalline Alloy

Giant magnetocaloric effect from reverse martensitic transformation in Ni–Mn–Ga–Cu ferromagnetic shape memory alloys

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