Martensitic Transformation, Magnetic and Mechanical Characteristics in Unidirectional Ni–Mn–Sn Heusler Alloy

Sun, Haodong; Jing, Chao; Zeng, Hongtao; Su, Yuan; Yang, Siyuan; Zhang, Yuanlei; Bachaga, T.; Zhou, Ting; Hou, Long; Ren, Wei

doi:10.3390/magnetochemistry8100136

Cited by 6 publications

(4 citation statements)

References 53 publications

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“…However, the coincidence of these thermo-magnetization curves close to the Curie temperatures of austenite and martensite phases, T C A and T C M , respectively, indicates that these transitions are of the second order. From these curves, the typical structural and transition temperatures are noticed as Ms = 261.0 K, Mf = 250.4 K, As = 262.2 K, Af = 274.1 K, T C M = 172.0 K, and T C A = 307.3 K. Also, it has been discovered elsewhere [78] that the magnetic transformation temperature of the austenite phase (Curie temperature T C A ) is approximately 325 K for Ni 50 Mn 36 Sn 14 alloys. In the regions of 230 K (Ms)-170 K (Mf) and 195 K (As)-255 K (Af), which correspond to martensitic and reverse martensitic transformations, respectively, dramatic changes in magnetization are seen below T C A .…”

Section: Magnetic and Shape Memory Alloysmentioning

confidence: 80%

“…Similarly, further authors have estimated that the magnetic transition from ferromagnetic (FM) to paramagnetic (PM) state can occur simultaneously with the structural transformation from austenite (AS) to martensite (MS) [79]. Referring to Sun et al [78], in the Ni 50 Mn 36 Sn 14 Heusler alloy, the temperature at which magnetic transformation occurred was roughly 325 K. In the ranges of 230 K (Ms)-170 K (Mf) and 195 K (As)-255 K (Af), respectively, dramatic changes in magnetization were seen below Curie temperature, which was related to MT and reverse MT. As a further feature, the zero-field cooling (ZFC) curve demonstrated a blocking temperature TB (65 K) inflection point that indicated the presence of magnetically inhomogeneous states.…”

Section: Magnetic and Shape Memory Alloysmentioning

confidence: 99%

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Crystal Structure and Properties of Heusler Alloys: A Comprehensive Review

Wederni,

Daza,

Ben Mbarek

et al. 2024

Metals

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Heusler alloys, which were unintentionally discovered at the start of the 20th century, have become intriguing materials for many extraordinary functional applications in the 21st century, including smart devices, spintronics, magnetic refrigeration and the shape memory effect. With this review article, we would like to provide a comprehensive review on the recent progress in the development of Heusler alloys, especially Ni-Mn based ones, focusing on their structural crystallinity, order-disorder atoms, phase changes and magnetic ordering atoms. The characterization of the different structures of these types of materials is needed, where a detailed exploration of the crystal structure is presented, encompassing the influence of temperature and compositional variations on the exhibited phases. Hence, this class of materials, present at high temperatures, consist of an ordered austenite with a face-centered cubic (FCC) superlattice as an L21 structure, or body-centered cubic (BCC) unit cell as a B2 structure. However, a low-temperature martensite structure can be produced as an L10, 10M or 14M martensite structures. The crystal lattice structure is highly dependent on the specific elements comprising the alloy. Additionally, special emphasis is placed on phase transitions within Heusler alloys, including martensitic transformations ranging above, near or below room temperature and magnetic transitions. Therefore, divers’ crystallographic defects can be presented in such types of materials affecting their structural and magnetic properties. Moreover, an important property of Heusler compounds, which is the ability to regulate the valence electron concentration through element substitution, is discussed. The possible challenges and remaining issues are briefly discussed.

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Section: Magnetic and Shape Memory Alloysmentioning

confidence: 80%

Section: Magnetic and Shape Memory Alloysmentioning

confidence: 99%

Crystal Structure and Properties of Heusler Alloys: A Comprehensive Review

Wederni,

Daza,

Ben Mbarek

et al. 2024

Metals

View full text Add to dashboard Cite

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“…These losses occur as a result of the alternating magnetic flux in the core. Their sources are magnetic hysteresis [14][15][16][17] and eddy currents [18,19]. Hysteresis losses are proportional to the surface area of the magnetic hysteresis loop in the transformer core.…”

Section: Fundamentals Of Transformer Temperature Distribution 21 Heat...mentioning

confidence: 99%

The Tools and Parameters to Consider in the Design of Power Transformer Cooling Systems

Goscinski,

Nadolny,

Nawrowski

et al. 2023

Energies

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Transformers are the most important elements of electric power systems. Many conditions must be met for power transformers to work properly. One of them is a low operating temperature. This condition will be met if the transformer cooling system is properly designed. One of the components of a cooling system is insulating liquid. The heat transfer coefficient α of liquid determines its ability to cool the transformer. The higher its value, the more effectively the liquid transfers heat to the environment. This article describes the influence of the position of the heat source, which is usually in the windings of the transformer, on the coefficient α value of the insulating liquid. The vertical and horizontal positions of the heat source were analyzed. The coefficient α was analyzed at different points of the heat source. The tests were carried out for mineral oil and various esters. Heat transfer coefficient measurements were carried out for various surface heat loads of the heat source. It has been proven that, in the case of a horizontal heat source, the coefficient α has a value several dozen percent higher than in the case of a vertical source. It has been proven that the coefficient α has different values in different places of the heat source. Regardless of the location, the highest value of the coefficient α occurred in the lower part of the heat source.

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“…Setting aside the case of micro-or nanostructured materials which involve specific mechanisms [30][31][32] and going beyond the simple aspect of sample purity or secondary phase content, the sample synthesis technique may exert an extrinsic control on the phase transition and therefore significantly affect the magnetocaloric performances. One of the most typical examples is the great sensitivity of martensitic transitions to microstructural details [33][34][35][36][37][38].…”

Section: Introductionmentioning

confidence: 99%

Structure, Microstructure and Magnetocaloric/Thermomagnetic Properties at the Early Sintering of MnFe(P,Si,B) Compounds

Qianbai,

Yibole,

Guillou

2024

Metals

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Minimizing the sintering time while ensuring high performances is an important optimization step for the preparation of magnetocaloric or thermomagnetic materials produced by powder metallurgy. Here, we study the influence of sintering time on the properties of a Mn0.95Fe1P0.56Si0.39B0.05 compound. In contrast to former reports investigating different annealing temperatures during heat treatments of several hours or days, we pay special attention to the earliest stages of sintering. After ball-milling and powder compaction, 2 min sintering at 1100 °C is found sufficient to form the desired Fe2P-type phase. Increasing the sintering time leads to a sharper first-order magnetic transition, a stronger latent heat, and usually to a larger isothermal entropy change, though not in all cases. As demonstrated by DSC or magnetization measurements, these parameters present dissimilar time evolutions, highlighting the existence of various underlying mechanisms. Chemical inhomogeneities are likely responsible for broadened transitions for the shortest sinterings. The development of strong latent heat requires longer sinterings than those for sharpening the magnetic transition. The microstructure may play a role as the average grain size progressively increases with the sintering time from 3.5 μm (2 min) to 30.1 μm (100 h). This systematic study has practical consequences for optimizing the preparation of MnFe(P,Si,B) compounds, but also raises intriguing questions on the influence of the microstructure and of the chemical homogeneity on magnetocaloric or thermomagnetic performances.

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Martensitic Transformation, Magnetic and Mechanical Characteristics in Unidirectional Ni–Mn–Sn Heusler Alloy

Cited by 6 publications

References 53 publications

Crystal Structure and Properties of Heusler Alloys: A Comprehensive Review

Crystal Structure and Properties of Heusler Alloys: A Comprehensive Review

The Tools and Parameters to Consider in the Design of Power Transformer Cooling Systems

Structure, Microstructure and Magnetocaloric/Thermomagnetic Properties at the Early Sintering of MnFe(P,Si,B) Compounds

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