High and Ultra-High Coercive Materials in Spring-Exchange Systems—Review, Simulations and Perspective

The paper refers to the spring-exchange magnetic systems containing magnetically soft and hard phases. This work consists of two parts. The first part is a brief review of hard magnetic materials, with special attention paid to ultra-high coercive compounds, as well as selected spring-exchange syste...

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Veröffentlicht in:	Materials 2022-09, Vol.15 (19), p.6506
1. Verfasser:	Chrobak, Artur
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Sprache:	eng
Schlagworte:	Anisotropy Coercivity Composite materials Crystal structure Electric transformers Energy Exchanging Magnetic fields Magnetic materials Magnetic properties Magnetism Magnets, Permanent Neodymium Permanent magnets Rare earth elements Simulation Simulation methods Technology application
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description	The paper refers to the spring-exchange magnetic systems containing magnetically soft and hard phases. This work consists of two parts. The first part is a brief review of hard magnetic materials, with special attention paid to ultra-high coercive compounds, as well as selected spring-exchange systems. The second part is a theoretical discussion based on the Monte Carlo micromagnetic simulations about the possible enhancement of the hard magnetic properties of systems composed of magnetically soft, as well as high and ultra-high coercive, phases. As shown, the analyzed systems reveal the potential for improving the \|BH\|max parameter, filling the gap between conventional and Nd-based permanent magnets. Moreover, the carried-out simulations indicate the advantages and limitations of the spring-exchange composites, which could lead to a reduction in rare earth elements in permanent magnet applications.
doi_str_mv	10.3390/ma15196506
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subjects	Anisotropy Coercivity Composite materials Crystal structure Electric transformers Energy Exchanging Magnetic fields Magnetic materials Magnetic properties Magnetism Magnets, Permanent Neodymium Permanent magnets Rare earth elements Simulation Simulation methods Technology application
title	High and Ultra-High Coercive Materials in Spring-Exchange Systems—Review, Simulations and Perspective
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