Role of interplay of austenite and martensite phase fractions on the magnetocaloric and magnetoresistance effects across the martensite transition in Ni45Mn44Sn7In4 Heusler alloy near room temperature

Abstract: The influence of martensite and austenite phase fractions on the magnetocaloric and magnetoresistance (MR) properties has been studied across the first-order magneto-structural martensite transition in the polycrystalline Ni45Mn44Sn7In4 Heusler alloy near room temperature. Here, we have studied in detail the structural, calorimetric, magnetic, magnetocaloric, and magneto-resistance properties of the Ni45Mn44Sn7In4 Heusler alloy. The detailed investigation of thermal and magnetic field path dependent magnetizat… Show more

“…It is noticed from Figure b,c that the magnetic hysteresis has been reduced with substitution and addition of Gd in Ni 45 Co 5 Mn 37 In 12 Si 1 alloy. The notable reduction in magnetization of GS and GA could be due to the lattice distortion and the presence of the secondary phase in these alloys, which can lead to changes in Mn–Mn distance. ,,,,, As a result of the foregoing, the magnetization (Δ M ) of Gd-substituted and Gd-added alloys decreased as ∼20 and ∼18 emu/g, respectively, whereas the parent alloy’s magnetization is ∼90 emu/g at 2 T.…”

“…The core-level XPS of Ni 2p, Co 2p, Gd 4d, Mn 2p, In 3d, and Si 2p for GA sample was recorded and is presented in Figure . The elemental binding energies of Ni 2p 3/2 (2p 1/2 ), Co 2p 3/2 (2p 1/2 ), Gd 4d 5/2 (4d 3/2 ), Mn 2p 3/2 (2p 1/2 ), In 3d 5/2 (3d 3/2 ), and Si 2p 3/2 (2p 1/2 ) are ∼851.7 eV (∼873.09 eV), ∼779.8 eV (∼796.9 eV),∼140.74 eV (145.81 eV), ∼640.74 eV (∼653.02 eV), ∼443.7 eV (∼451.35 eV), and ∼101.1 eV (∼105.6), respectively, which also confirms that all the constituent elements in Ni 45 Co 5 Mn 37 In 12 Si 1 are their respective metallic states of Ni 2p, Co 2p, Mn 2p, In 3d, and Si 2p, and seen untraceable oxidation during synthesis of alloys, consistent with the previous reports in the literature. − The core-level XPS spectra of Ni 2p, Co 2p, Mn 2p, In 3d, and Si 2p of NM alloy is seen in Figure S3, Supporting Information. To be specific, intensity variation shows that doping Gd in NM alloy plays an important role in the core level as it decreases the intensity of the element.…”

“…The notable reduction in magnetization of GS and GA could be due to the lattice distortion and the presence of the secondary phase in these alloys, which can lead to changes in Mn−Mn distance. 41,53,55,56,60,61 As a result of the foregoing, the magnetization (ΔM) of Gd-substituted and Gd-added alloys decreased as ∼20 and ∼18 emu/g, respectively, whereas the parent alloy's magnetization is ∼90 emu/g at 2 T. Furthermore, it is to be noted that M versus H plot of NM has shown the same path without any magnetic hysteresis from 313 to 343 K upon increasing and decreasing magnetic field upto 2 T. Above 343 K, there is a clear indication of magnetic hysteresis in the temperature range of 363−393 K, as seen in Figure 8a. Nevertheless, this magnetic hysteresis is significantly diminished in the samples of Gd-substituted and Gd-added alloys, as seen in Figure 8b,c.…”

Realization of Enhanced Refrigeration Capacity with Non-Hysteretic Behavior in Ni₄₀Gd₅Co₅Mn₃₇In₁₂Si₁ Alloy Near Room Temperature at 2T

“…It is noticed from Figure b,c that the magnetic hysteresis has been reduced with substitution and addition of Gd in Ni 45 Co 5 Mn 37 In 12 Si 1 alloy. The notable reduction in magnetization of GS and GA could be due to the lattice distortion and the presence of the secondary phase in these alloys, which can lead to changes in Mn–Mn distance. ,,,,, As a result of the foregoing, the magnetization (Δ M ) of Gd-substituted and Gd-added alloys decreased as ∼20 and ∼18 emu/g, respectively, whereas the parent alloy’s magnetization is ∼90 emu/g at 2 T.…”

“…The core-level XPS of Ni 2p, Co 2p, Gd 4d, Mn 2p, In 3d, and Si 2p for GA sample was recorded and is presented in Figure . The elemental binding energies of Ni 2p 3/2 (2p 1/2 ), Co 2p 3/2 (2p 1/2 ), Gd 4d 5/2 (4d 3/2 ), Mn 2p 3/2 (2p 1/2 ), In 3d 5/2 (3d 3/2 ), and Si 2p 3/2 (2p 1/2 ) are ∼851.7 eV (∼873.09 eV), ∼779.8 eV (∼796.9 eV),∼140.74 eV (145.81 eV), ∼640.74 eV (∼653.02 eV), ∼443.7 eV (∼451.35 eV), and ∼101.1 eV (∼105.6), respectively, which also confirms that all the constituent elements in Ni 45 Co 5 Mn 37 In 12 Si 1 are their respective metallic states of Ni 2p, Co 2p, Mn 2p, In 3d, and Si 2p, and seen untraceable oxidation during synthesis of alloys, consistent with the previous reports in the literature. − The core-level XPS spectra of Ni 2p, Co 2p, Mn 2p, In 3d, and Si 2p of NM alloy is seen in Figure S3, Supporting Information. To be specific, intensity variation shows that doping Gd in NM alloy plays an important role in the core level as it decreases the intensity of the element.…”

“…The notable reduction in magnetization of GS and GA could be due to the lattice distortion and the presence of the secondary phase in these alloys, which can lead to changes in Mn−Mn distance. 41,53,55,56,60,61 As a result of the foregoing, the magnetization (ΔM) of Gd-substituted and Gd-added alloys decreased as ∼20 and ∼18 emu/g, respectively, whereas the parent alloy's magnetization is ∼90 emu/g at 2 T. Furthermore, it is to be noted that M versus H plot of NM has shown the same path without any magnetic hysteresis from 313 to 343 K upon increasing and decreasing magnetic field upto 2 T. Above 343 K, there is a clear indication of magnetic hysteresis in the temperature range of 363−393 K, as seen in Figure 8a. Nevertheless, this magnetic hysteresis is significantly diminished in the samples of Gd-substituted and Gd-added alloys, as seen in Figure 8b,c.…”

Realization of Enhanced Refrigeration Capacity with Non-Hysteretic Behavior in Ni₄₀Gd₅Co₅Mn₃₇In₁₂Si₁ Alloy Near Room Temperature at 2T

“…In these alloys, the transformations can be induced by mechanical stress, temperature and/or external magnetic field. Functional effects of these materials are: magnetic shape memory [1], magnetocaloric [2], magneto-resistance [3], exchange-bias [4], barocaloric [5] or elastocaloric [6].…”

Ni-Mn-Sn-Cu Alloys after Thermal Cycling: Thermal and Magnetic Response

“…This leads to intrinsic irreversibilities in both isothermal entropy and adiabatic temperature changes, which can drastically reduce the cooling efficiency [18][19][20][21]. In order to optimize the cooling efficiency, huge efforts have been made to control the characteristics of the magnetic transition [22,23]. In particular, in NiMnGa, Pt-substitution on the Ni site appears as an excellent route, since one obtains a series of magnetic shape-memory alloys with properties similar to NiMnGa, but with a larger internal strain [2,11,14].…”

Direct and Indirect Determination of the Magnetocaloric Effect in the Heusler Compound Ni1.7Pt0.3MnGa