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New structural features and pinning-evolved coercivity mechanism: A potential route for developing high coercivities in anisotropic Sm-Fe-N material

Liming Ye, Feng-qing Wang, Yang Liu, Haoran Zhou, Lei Liu, Yong Ding, Yingli Sun, Aru Yan

2024Journal of Materials Research and Technology10 citationsDOIOpen Access PDF

Abstract

Sm-Fe-N material holds immense promise as new material for developing next generation permanent magnets. However, the achievement of high coercivity in this material remains a big challenge, and moreover new coercivity theories beyond the commonly considered nucleation-type mechanism needs exploration. This study describes both the yielding of anisotropic Sm-Fe-N powders with high coercivities and the discovery of new coercivity mechanism by a systematic study using a designed milling preparation method. As a result, a random-direction cleavage behavior with unexpected XRD peak shifts and formation of new micron-sized flower-like particles were found in the yielded Sm-Fe-N powders. The grain size of the powders is of nanoscale dimension and refines gradually as the milling time increases. The measured coercivity is up to 15.0 kOe, which is a substantial increase of approximately 36.4% compared to the original commercial powders and among the highest reported values via the milling preparation method (commonly below 13 kOe). The yielded powders also demonstrate a new dual-type coercivity mechanism (combing both nucleation-type and pinning-type control effect), and the improved pining effect contributes to the high coercivities. This study opens the door of utilizing pinning effect for achieving high coercivities in anisotropic Sm-Fe-N material.

Topics & Concepts

CoercivityMaterials scienceNucleationAnisotropyCondensed matter physicsGrain sizeMetallurgyThermodynamicsOpticsPhysicsMagnetic Properties of AlloysHydrogen Storage and MaterialsMagnetic and transport properties of perovskites and related materials
New structural features and pinning-evolved coercivity mechanism: A potential route for developing high coercivities in anisotropic Sm-Fe-N material | Litcius