Effect of the Boron Addition on the Structure of the Ni-Mn-Co-In Alloys

Prusik, Krystian; Matyja, Edyta; Zubko, Maciej; Kubisztal, M.; Chrobak, A.

doi:10.12693/aphyspola.130.1023

Cited by 5 publications

(2 citation statements)

References 12 publications

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“…The ductility of Ni-Mn-based alloys can be improved by doping the B element, introducing second-phase particles at grain boundaries. In 2011, Nong et al [ 61 ] studied Ni-Mn-Sb alloys with B doping and found that if the content of the B element was increased from 1 at.% to 3 at.%, the Curie temperature increased from 330 K to 345 K, and the martensitic transformation temperature decreased from 300 K to 262 K. Prusik et al [ 62 ] investigated the Ni-Mn-Co-In alloy doped with the B element and found that the B element facilitated the formation of “Co-rich and In-deficient” γ phase and M 23 B 6 phase. When the B content reached 1 at.%, the second phases formed a “sub grain “ structure within the grain interiors and at the grain boundaries.…”

Section: The Effects Of Doping On the Toughness Of Ni-mn-based Alloysmentioning

confidence: 99%

Toughening of Ni-Mn-Based Polycrystalline Ferromagnetic Shape Memory Alloys

Ma,

Zhang,

Zheng

et al. 2023

Materials

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Solid-state refrigeration technology is expected to replace conventional gas compression refrigeration technology because it is environmentally friendly and highly efficient. Among various solid-state magnetocaloric materials, Ni-Mn-based ferromagnetic shape memory alloys (SMAs) have attracted widespread attention due to their multifunctional properties, such as their magnetocaloric effect, elastocaloric effect, barocaloric effect, magnetoresistance, magnetic field-induced strain, etc. Recently, a series of in-depth studies on the thermal effects of Ni-Mn-based magnetic SMAs have been carried out, and numerous research results have been obtained. It has been found that poor toughness and cyclic stability greatly limit the practical application of magnetic SMAs in solid-state refrigeration. In this review, the influences of element doping, microstructure design, and the size effect on the strength and toughness of Ni-Mn-based ferromagnetic SMAs and their underlying mechanisms are systematically summarized. The pros and cons of different methods in enhancing the toughness of Ni-Mn-based SMAs are compared, and the unresolved issues are analyzed. The main research directions of Ni-Mn-based ferromagnetic SMAs are proposed and discussed, which are of scientific and technological significance and could promote the application of Ni-Mn-based ferromagnetic SMAs in various fields.

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Section: The Effects Of Doping On the Toughness Of Ni-mn-based Alloysmentioning

confidence: 99%

Toughening of Ni-Mn-Based Polycrystalline Ferromagnetic Shape Memory Alloys

Ma,

Zhang,

Zheng

et al. 2023

Materials

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“…That proves the L2 1 ordering. The space group of the matrix is F m3m and the lattice parameter a 0 = 5.98 Å [11]. The structure of the precipitates of B010-B100 alloys were determined as M 23 B 6 .…”

Section: Structure Of the Alloysmentioning

confidence: 99%

Magnetic Properties and Structure of the Ni-Co-Mn-In Alloys with the Boron Addition

et al. 2017

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Series of Ni45.5−xCo4.5Mn36.6In13.4Bx (at.%, x = 0, 0.05, 0.1, 0.5, 1.0) polycrystalline magnetic shape memory alloys were examined in terms of the magnetic properties, structure and transition temperatures. Depending on the boron concentration single or two phase alloys microstructures were observed. Additionally, the martensitic transformation temperatures decreases with the boron addition. Magnetic-field induced transformation occurs for the alloys with the boron addition up to 0.1 at.%. For alloys with 0.5 and 1.0 at.% of B transformation is hindered.

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