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Enhancing the Elastocaloric Cooling Stability of NiFeGa Alloys via Introducing Pores
Author(s) -
Imran Muhammad,
Zhang Xuexi,
Qian Mingfang,
Geng Lin
Publication year - 2020
Publication title -
advanced engineering materials
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.938
H-Index - 114
eISSN - 1527-2648
pISSN - 1438-1656
DOI - 10.1002/adem.201901140
Subject(s) - materials science , pseudoelasticity , porosity , austenite , refrigeration , alloy , shape memory alloy , hysteresis , composite material , adiabatic process , compressive strength , casting , compression (physics) , metallurgy , martensite , thermodynamics , microstructure , quantum mechanics , physics
Elastocaloric cooling stability is an essential factor of solid‐state refrigeration to become a promising candidate in replacing the conventional vapor compression technology. Herein, Ni 53.5 Fe 19.9 Ga 26.6 foam with 53% porosity is fabricated by a replication casting technique and its elastocaloric properties compared with Ni 53 Fe 19.4 Ga 27.6 bulk alloy. NiFeGa foam expresses reversible superelasticity with strain ≈3.9% above austenite finishing temperature and also exhibits an adiabatic temperature change of 2.8 K smaller than its bulk counterpart 5.8 K. The compressive cyclic test reveals that foam shows better cyclic performance up to 100 cycles over bulk sample under the same loading effect. The enhanced cyclic stability in foam achieves due to pores and narrow hysteresis energy loss.