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Strategy of magnetic hardening region regulation enables a record enhanced energy product and high coercivity in Nd‐Fe‐B magnets

Zhi Jia, Yuhao Li, Xin‐Tong Yang, Shuai Cao, Guangfei Ding, Shuai Guo, Xiaodong Fan, Yu-Heng Xie, Zhi‐Wei Xiong, Renjie Chen, Aru Yan

2024Rare Metals19 citationsDOI

Abstract

Abstract By developing high comprehensive performance (( BH ) max + H cj ), Nd‐Fe‐B magnets can operate stably in high‐temperature applications, greatly expanding the application scenarios of them. Unfortunately, there is a constraint relationship between coercivity ( H cj ) and maximum magnetic energy product (( BH ) max ), and an increase in H cj always accompanies a decrease in ( BH ) max . Here, the excellent comprehensive magnetic performance of up to 86.54, namely ( BH ) max of 42.33 MGOe and H cj of 44.21 kOe, is unprecedented in the sintered Nd‐Fe‐B magnets. This magnet is obtained by designing a unique grain structure through micrometallurgical reactions to prepare a matrix with excellent comprehensive performance, and then by stepwise diffusion, the ( BH ) max and H cj of the magnet are simultaneously enhanced. The magnet prepared in this way has a “double‐shell core” structure and Tb segregation distribution inside the core. The working temperature of the magnet in this work reached 280 °C, providing a new approach for the development of high‐performance Nd‐Fe‐B magnets.

Topics & Concepts

CoercivityMaterials scienceMagnetHardening (computing)Condensed matter physicsEngineering physicsNuclear magnetic resonanceMechanical engineeringComposite materialEngineeringPhysicsLayer (electronics)Magnetic Properties of AlloysHydrogen Storage and MaterialsMagnetic and transport properties of perovskites and related materials
Strategy of magnetic hardening region regulation enables a record enhanced energy product and high coercivity in Nd‐Fe‐B magnets | Litcius