Elastocaloric and magnetocaloric effects in Ni-Mn-Sn(Cu) shape-memory alloy

Castillo-Villa, Pedro O.; Mañosa, Lluı́s; Planes, Antoni; Soto-Parra, Daniel; Sánchez-Llamazares, J. L.; Flores‐Zúñiga, H.; Frontera, C.

doi:10.1063/1.4790140

Cited by 111 publications

(41 citation statements)

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“…Although the giant ECE has been known of for some time, there is a lack of available scientific data needed for the successful design and implementation, or optimization, of multicomponent ECE systems. SMAs have been studied for their giant ECE via stress‐induced martensitic transformation and include NiTi, NiFeGa, CuZnAl, NiMnGaFe, NiMnGaCo, NiMnSn(Cu), and NiCoMnIn . These alloys have been reported to exhibit stress‐induced isothermal entropy changes of around 30, 10–20, 22.8, 5.5, 2.5, 1.75, and 5.5 J kg −1 K −1 under the stresses of 500, 150, 105, 9.3, 9.8, 5.24, and 75 MPa, respectively.…”

Section: Introductionmentioning

confidence: 99%

Orientation Dependence of the Elastocaloric Effect in Ni₅₄Fe₁₉Ga₂₇ Ferromagnetic Shape Memory Alloy

Bruno

Караман

Chumlyakov

2017

Physica Status Solidi (b)

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The crystallographic anisotropy of elastocaloric effect (ECE) and relative cooling power (RCP) in Ni 54 Fe 19 Ga 27 shape memory alloy single crystals are studied via compression tests. Single crystals are studied along the [001], [123], and [011] austenite directions and yield different ECE behaviors and maximum RCPs for various strain levels. A thermodynamic framework using the Helmholtz free energy is employed to analyze the total entropy change as a function of strain. Thermodynamic losses are computed from the mechanical hysteresis of superelasticity experiments to quantify the strain dependent RCP. It is found that the [001] orientation generates the highest maximal RCP of 738 J kg À1 when unloaded from 200 MPa. This is attributed mainly to the large superelastic temperature window of 45 K. However, loading the crystals to stresses higher than 200 MPa causes a multistep transformation in the [011] direction, thus reducing the alloy's overall RCP by 135 J kg À1 . This is a consequence of the negative entropy change and large transformation hysteresis generated by the second-stage transformation in the [011] direction. Interestingly, if only the first-stage transformation in [011] is employed for the ECE, the [011] direction yields the highest RCP compared to [001] and [123] for any strain up to 3.5%.

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Section: Introductionmentioning

confidence: 99%

Orientation Dependence of the Elastocaloric Effect in Ni₅₄Fe₁₉Ga₂₇ Ferromagnetic Shape Memory Alloy

Bruno

Караман

Chumlyakov

2017

Physica Status Solidi (b)

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“…[1][2][3] Recently, elastocaloric effect (eCE) primarily originated from lattice vibration or softening entropy changes has been reported in Cu-Zn-Al, 4,5 Ti-Ni-(Cu), [6][7][8] FePd, 9,10 and Ni-Mn-based shape memory alloys (SMAs). [11][12][13] In addition, some demonstration setups have been built to analysis the influence of various elastocaloric refrigerants, sample geometries, as well as operating conditions on the process functions. 14,15 Furthermore, an assessment report in 2014 from the U.S. Department of Energy on the alternative cooling technologies evaluated that the eCE cooling ranked the largest potential among all alternative non-vapor-compression technologies.…”

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confidence: 99%

Large and reversible elastocaloric effect in dual-phase Ni54Fe19Ga27 superelastic alloys

Sun

et al. 2015

Applied Physics Letters

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In this work, we report elastocaloric effect (eCE) in Ni-Fe-Ga polycrystalline alloys. By application of a uniaxial compressive stress of 170 MPa at 298 K, a large and recoverable temperature change of 4 K has been obtained in precipitates-containing Ni54Fe19Ga27 alloys. The degradation of eCE is insensitive to 100 loading-unloading cycles. In comparison, the loss of mechanical integrity occurs in the single-phase alloy suffering from only 10 superelastic cycles, implying a short fatigue life. Good mechanical properties, large and equivalent adiabatic temperature change (ΔT) under loading-unloading cycle render dual-phase Ni-Fe-Ga promising candidate materials for solid-state mechanical cooling application at ambient conditions.

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“…Recently another interesting mechanic-caloric effect, the elastocaloric effect (ECE), has attracted more attention into these systems. ECE consists in the isothermal entropy change or adiabatic temperature change within a material as a consequence of applying/removing of a stress, and in some bulk alloys like Cu-Zn-Al, Ni-Mn-SbCo, and Ni-Mn-Sn(Cu) a notable ECE has been observed [2][3][4][5]. It is a well-known fact that thermo-mechanical characterization is the principal way to investigate the actuating properties of these materials and to indicate the possibility of an optimization of their functional performance.…”

Section: Introductionmentioning

confidence: 99%

“…It should be emphasized that magnetically ordered SMAs, called magnetic shape memory materials, exhibit excellent ordinary shape memory characteristics (e.g., [2][3][4][5]). In this work, melt spun ribbons of the ferromagnetic SMA, Ni 55 Fe 16 Ga 29 (at.%), and metamagnetic SMA, Ni 50 Mn 40 Sn 10 (at.%), have been prepared and characterized under reduced values of the external stress preferable for ECE applications.…”

Section: Introductionmentioning

confidence: 99%

Shape memory behavior of Ni-Fe-Ga and Ni-Mn-Sn ribbons

Villa¹,

Agilar-Ortiz

Álvarez-Alonso

et al. 2015

MATEC Web of Conferences

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Abstract. Magnetic Shape Memory Alloys exhibit multifunctional properties due the martensitic transformation (MT) and accompanying changes in the magnetic subsystem. In this work, melt spun ribbons of nominal composition Ni55Fe16Ga29 (R1) and Ni50Mn40Sn10 (R2) have been produced and characterized by the calorimetric, thermomechanical, mechanical, microscopic and X-ray measurements. The effect of short annealing on MT and thermo-mechanical properties is rather modest and in the case of R2 enhances its brittleness. R1 and R2 as-spun ribbons show MT at TM ~ 340 K and ~ 420 K, respectively. The strain-stress curves for Ni-Fe-Ga in austenitic phase indicate good visco-elastic properties, although the superelastic effect was not well pronounced. Ni-Fe-Ga as-cast and annealed samples, as well as the as-cast Ni-Mn-Sn ribbons, present a shape memory effect with an anomalous contraction and elongation at low external stresses in the course of the forward and reverse MT, consequence of the compressive internal stresses.

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Elastocaloric and magnetocaloric effects in Ni-Mn-Sn(Cu) shape-memory alloy

Cited by 111 publications

References 20 publications

Orientation Dependence of the Elastocaloric Effect in Ni₅₄Fe₁₉Ga₂₇ Ferromagnetic Shape Memory Alloy

Orientation Dependence of the Elastocaloric Effect in Ni₅₄Fe₁₉Ga₂₇ Ferromagnetic Shape Memory Alloy

Large and reversible elastocaloric effect in dual-phase Ni54Fe19Ga27 superelastic alloys

Shape memory behavior of Ni-Fe-Ga and Ni-Mn-Sn ribbons

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Elastocaloric and magnetocaloric effects in Ni-Mn-Sn(Cu) shape-memory alloy

Cited by 111 publications

References 20 publications

Orientation Dependence of the Elastocaloric Effect in Ni54Fe19Ga27 Ferromagnetic Shape Memory Alloy

Orientation Dependence of the Elastocaloric Effect in Ni54Fe19Ga27 Ferromagnetic Shape Memory Alloy

Large and reversible elastocaloric effect in dual-phase Ni54Fe19Ga27 superelastic alloys

Shape memory behavior of Ni-Fe-Ga and Ni-Mn-Sn ribbons

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Orientation Dependence of the Elastocaloric Effect in Ni₅₄Fe₁₉Ga₂₇ Ferromagnetic Shape Memory Alloy

Orientation Dependence of the Elastocaloric Effect in Ni₅₄Fe₁₉Ga₂₇ Ferromagnetic Shape Memory Alloy