Size-dependent structure and magnetocaloric properties of Fe-based glass-forming alloy powders | Zendy

Qiang Luo | Zendy; Fengxia Ye | Zendy; Changjun Huang | Zendy; Jin Jiao | Zendy; Md. Anisur Rahman | Zendy; Peng Yu | Zendy; Jie Li | Zendy; Jun Shen | Zendy

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Size-dependent structure and magnetocaloric properties of Fe-based glass-forming alloy powders

Author(s) -

Qiang Luo,

Fengxia Ye,

Changjun Huang,

Jin Jiao,

Md. Anisur Rahman,

Peng Yu,

Jie Li,

Jun Shen

Publication year - 2016

Publication title -

aip advances

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.421

H-Index - 58

ISSN - 2158-3226

DOI - 10.1063/1.4945754

Subject(s) - magnetic refrigeration , materials science , alloy , particle size , microstructure , grain size , refrigerant , degree (music) , thermodynamics , metallurgy , condensed matter physics , magnetic field , magnetization , chemistry , physics , gas compressor , quantum mechanics , acoustics

We investigated the influence of particle size on the microstructure and magnetocaloric effect of Fe-based alloy powders (11 μm to 100 μm in diameter). The degree of structure order varies with the powder size. The 11 μm to 18 μm powders show the largest peak magnetic entropy change (MEC). Increasing the degree of structure order tends to decrease the maximum MEC. Nevertheless, enhancement of refrigerant capacity and MEC (above 70 K) is achieved when the crystalline phase content is ∼50% (above 75 μm) in the 75 μm to 100 μm powders. Exponent n of the field dependence of MEC increases with the decrease in powder size above 22.5 K. The size dependence of the structure and properties is associated with the fact that a larger particle has a slower cooling rate and takes a longer time to form medium-to-long range ordered structures

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