Micromagnetic Simulations for Coercivity Improvement through Nano-Structuring of Rare-Earth Free L1$_0$-FeNi Magnets

Alexander Kovacs; Andreas Kaidatzis; Dimitris Niarchos; George Giannopoulos; Harald Oezelt; Johann Fischbacher; Michael Farle; Ruslan Salikhov; Thomas Schrefl

arxiv: 1703.03684 · v2 · pith:KYZX2KBRnew · submitted 2017-03-10 · ⚛️ physics.comp-ph · cond-mat.mtrl-sci

Micromagnetic Simulations for Coercivity Improvement through Nano-Structuring of Rare-Earth Free L1₀-FeNi Magnets

Alexander Kovacs , Johann Fischbacher , Harald Oezelt , Thomas Schrefl , Andreas Kaidatzis , Ruslan Salikhov , Michael Farle , George Giannopoulos

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Dimitris Niarchos

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classification ⚛️ physics.comp-ph cond-mat.mtrl-sci

keywords fenienergymagnetsmaximumorderedproductfreemicromagnetic

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In this work we investigate the potential of tetragonal L1$_0$ ordered FeNi as candidate phase for rare earth free permanent magnets taking into account anisotropy values from recently synthesized, partially ordered FeNi thin films. In particular, we estimate the maximum energy product ($BH$)$_\mathrm{max}$ of L1$_0$-FeNi nanostructures using micromagnetic simulations. The maximum energy product is limited due to the small coercive field of partially ordered L1$_0$-FeNi. Nano-structured magnets consisting of 128 equi-axed, platelet-like and columnar-shaped grains show a theoretical maximum energy product of 228 kJ/m$^3$, 208 kJ/m$^3$, 252 kJ/m$^3$, respectively.

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Micromagnetic Simulations for Coercivity Improvement through Nano-Structuring of Rare-Earth Free L1₀-FeNi Magnets

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