N. I. Polushkin scite author profile

Manipulation of magnetism using laser light is considered as a key to the advancement of data storage technologies. Until now, most approaches seek to optically switch the direction of magnetization rather than to reversibly manipulate the ferromagnetism itself. Here, we use ∼100 fs laser pulses to reversibly switch ferromagnetic ordering on and off by exploiting a chemical order-disorder phase transition in FeAl, from the B2 to the A2 structure and vice versa. A single laser pulse above a threshold fluence causes nonferromagnetic B2 FeAl to disorder and form the ferromagnetic A2 structure. Subsequent laser pulsing below the threshold reverses the surface to B2 FeAl, erasing the laser-induced ferromagnetism. Simulations reveal that the order-disorder transition is regulated by the extent of surface supercooling; above the threshold for complete melting throughout the film thickness, the liquid phase can be deeply undercooled before solidification. As a result, the vacancy diffusion in the resolidified region is limited and the region is trapped in the metastable chemically disordered state. Laser pulsing below the threshold forms a limited supercooled surface region that solidifies at sufficiently high temperatures, enabling diffusion-assisted reordering. This demonstrates that ultrafast lasers can achieve subtle atomic rearrangements in bimetallic alloys in a reversible and nonvolatile fashion.

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Phase-Change Magnetic Memory: Rewritable Ferromagnetism by Laser Quenching of Chemical Disorder in Fe60Al40 Alloy

Polushkin

Oliveira

Vilar

et al. 2018

Phys. Rev. Applied

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In systems that store data magnetically, the information can be corrupted by external magnetic fields and by thermal fluctuations. One possible approach, which could solve both of these problems, is altering reversibly the magnetization magnitude instead of its direction. The authors propose such an alternative magnetic memory upon the basis of chemical order-disorder transformations in Fe-Al alloys. It is found out that room-temperature ferromagnetism in Fe 60 Al 40 thin-fim (≈40 nm) samples is recoverable after rapid resolidification of the alloy, which follows its irradiation by a short laser pulse with intensity sufficient for melting.

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N. I. Polushkin

Magnetic nanodot arrays produced by direct laser interference lithography

Laser-Rewriteable Ferromagnetism at Thin-Film Surfaces

Phase-Change Magnetic Memory: Rewritable Ferromagnetism by Laser Quenching of Chemical Disorder in Fe60Al40 Alloy

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