Tuning Fe[sub.2]Ti Distribution to Enhance Extrinsic Magnetic Properties of SmFe[sub.12]-Based Magnets

The ThMn[sub.12]-type SmFe[sub.12]-based rare-earth permanent magnet has attracted widespread attention due to its excellent intrinsic magnetic properties and high-temperature stability. However, the challenge in realizing continuous non-magnetic or weakly magnetic grain boundary phases equilibrated...

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Veröffentlicht in:	Crystals (Basel) 2024-06, Vol.14 (6)
Hauptverfasser:	Wei, Jinbo, Xu, Shuainan, Xu, Chengyuan, Liu, Xiaolian, Pan, Yu, Wang, Wei, Wu, Yue, Chen, Ping, Liu, Jun, Zhao, Lizhong, Zhang, Xuefeng
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Sprache:	eng
Schlagworte:	Grain boundaries Magnetic properties Magnets, Permanent
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creator	Wei, Jinbo Xu, Shuainan Xu, Chengyuan Liu, Xiaolian Pan, Yu Wang, Wei Wu, Yue Chen, Ping Liu, Jun Zhao, Lizhong Zhang, Xuefeng
description	The ThMn[sub.12]-type SmFe[sub.12]-based rare-earth permanent magnet has attracted widespread attention due to its excellent intrinsic magnetic properties and high-temperature stability. However, the challenge in realizing continuous non-magnetic or weakly magnetic grain boundary phases equilibrated with the SmFe[sub.12] main phase hinders the enhancement in extrinsic magnetic properties of the SmFe[sub.12]-based permanent magnet, especially for the coercivity. In this work, by controlling the cooling rate, the uniform distribution of paramagnetic Fe[sub.2]Ti phases at grain boundaries is achieved in the SmFe[sub.12]-based alloy ribbon, resulting in a high coercivity of 7.95 kOe. This improvement is attributed to the elimination of the impurity phase within the SmFe[sub.12] main phase and the magnetic isolation effect of the grain boundary phase composed of paramagnetic Fe[sub.2]Ti, which is directly observed by transmission electron microscopy and further confirmed by micromagnetic simulation. Moreover, first-principles calculations show that the V element can dope into Fe[sub.2]Ti and facilitate the transition of its paramagnetic state at room temperature. This study provides new insights into constructing weakly magnetic grain boundary phases for SmFe[sub.12]-based permanent magnets, offering a novel approach to enhance coercivity.
doi_str_mv	10.3390/cryst14060572
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However, the challenge in realizing continuous non-magnetic or weakly magnetic grain boundary phases equilibrated with the SmFe[sub.12] main phase hinders the enhancement in extrinsic magnetic properties of the SmFe[sub.12]-based permanent magnet, especially for the coercivity. In this work, by controlling the cooling rate, the uniform distribution of paramagnetic Fe[sub.2]Ti phases at grain boundaries is achieved in the SmFe[sub.12]-based alloy ribbon, resulting in a high coercivity of 7.95 kOe. This improvement is attributed to the elimination of the impurity phase within the SmFe[sub.12] main phase and the magnetic isolation effect of the grain boundary phase composed of paramagnetic Fe[sub.2]Ti, which is directly observed by transmission electron microscopy and further confirmed by micromagnetic simulation. Moreover, first-principles calculations show that the V element can dope into Fe[sub.2]Ti and facilitate the transition of its paramagnetic state at room temperature. 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However, the challenge in realizing continuous non-magnetic or weakly magnetic grain boundary phases equilibrated with the SmFe[sub.12] main phase hinders the enhancement in extrinsic magnetic properties of the SmFe[sub.12]-based permanent magnet, especially for the coercivity. In this work, by controlling the cooling rate, the uniform distribution of paramagnetic Fe[sub.2]Ti phases at grain boundaries is achieved in the SmFe[sub.12]-based alloy ribbon, resulting in a high coercivity of 7.95 kOe. This improvement is attributed to the elimination of the impurity phase within the SmFe[sub.12] main phase and the magnetic isolation effect of the grain boundary phase composed of paramagnetic Fe[sub.2]Ti, which is directly observed by transmission electron microscopy and further confirmed by micromagnetic simulation. Moreover, first-principles calculations show that the V element can dope into Fe[sub.2]Ti and facilitate the transition of its paramagnetic state at room temperature. 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title	Tuning Fe[sub.2]Ti Distribution to Enhance Extrinsic Magnetic Properties of SmFe[sub.12]-Based Magnets
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