Magnetocaloric effect， corrosion behavior and corrosion prevention of LaFe11.832-  x Ni  x Si1.4 alloy

Renhao WANG; Bin FU; Jie HAN; Jiaqi WANG; Jie HU

doi:10.11868/j.issn.1001-4381.2024.000761

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Journal of Materials Engineering ›› 2025, Vol. 53 ›› Issue (4) : 114-124. DOI: 10.11868/j.issn.1001-4381.2024.000761

RESEARCH ARTICLE

Magnetocaloric effect， corrosion behavior and corrosion prevention of LaFe_11.832- _x Ni _x Si_1.4 alloy

Renhao WANG ¹ ,
Bin FU ¹ ,
Jie HAN ² ,
Jiaqi WANG ¹ ,
Jie HU ³

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Abstract

To solve the corrosion problem of La（Fe， Si）₁₃ magnetic refrigeration material in the heat exchange medium， an attempt is made to partially replace Fe element with Ni element. The magnetocaloric properties of LaFe_11.832- _x Ni _x Si_1.4（x=0，0.1，0.2，0.3，mass fraction，the same below） alloys before and after the substitution， as well as the corrosion behavior in different media， are systematically studied. The results show that when the Ni content is less than 0.2， LaFe_11.832- _x Ni _x Si_1.4 can maintain good magnetocaloric performance. Its magnetic entropy change under a 2 T magnetic field can reach 15.31 J/（kg·K）（x=0.1） and 14.00 J/（kg· K）（x=0.2）， and the relative magnetic cooling capacity is 151.6 J/kg and 156.8 J/kg， respectively， with significantly reduced magnetic hysteresis loss. In deionized water， the corrosion current I _corr of LaFe_11.832- _x Ni _x Si_1.4 alloy decreases from 2.6159 μA/cm² to 2.0863 μA/cm² with increasing Ni content. The maximum corrosion inhibition efficiency of LaFe_11.832- _x Ni _x Si_1.4 alloy in combined inhibitor of 4 g/L BTA+1 g/L Na₂MoO₄·2H₂O is 77.06%， showing a good corrosion inhibition effect. The LaFe_11.832- _x Ni _x Si_1.4（x≤0.2） alloy with 4 g/L BTA+1 g/L Na₂MoO₄·2H₂O can be used as an alternative combination of working fluid and medium for practical magnetic refrigerators.

Key words

La（Fe， Si）₁₃ alloy / magnetothermal effect / corrosion behavior / corrosion inhibitor

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Renhao WANG , Bin FU , Jie HAN , et al . Magnetocaloric effect， corrosion behavior and corrosion prevention of LaFe_11.832- _x Ni _x Si_1.4 alloy. Journal of Materials Engineering. 2025, 53(4): 114-124 https://doi.org/10.11868/j.issn.1001-4381.2024.000761

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Received	Revised	Published
09 Nov 2024	02 Dec 2024	20 Apr 2025
Issue Date
18 Jun 2025

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