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Autori principali: Díaz, Eva, Anadón, Alberto, Olleros-Rodríguez, Pablo, Singh, Harjinder, Damas, Héloïse, Perna, Paolo, Morassi, Martina, Lemaître, Aristide, Hehn, Michel, Gorchon, Jon
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.00474
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author Díaz, Eva
Anadón, Alberto
Olleros-Rodríguez, Pablo
Singh, Harjinder
Damas, Héloïse
Perna, Paolo
Morassi, Martina
Lemaître, Aristide
Hehn, Michel
Gorchon, Jon
author_facet Díaz, Eva
Anadón, Alberto
Olleros-Rodríguez, Pablo
Singh, Harjinder
Damas, Héloïse
Perna, Paolo
Morassi, Martina
Lemaître, Aristide
Hehn, Michel
Gorchon, Jon
contents Electrical current pulses can be used to manipulate magnetization efficiently via spin-orbit torques (SOTs). Pulse durations as short as a few picoseconds have been used to switch the magnetization of ferromagnetic films, reaching the THz regime. However, little is known about the reversal mechanisms and energy requirements in the ultrafast switching regime. In this work, we quantify the energy cost for magnetization reversal over 7 orders of magnitude in pulse duration, in both ferromagnetic and ferrimagnetic samples, bridging quasi-static spintronics and femtomagnetism. To this end, we develop a method to stretch picosecond pulses generated by a photoconductive switch by an order of magnitude. Thereby, we can create current pulses from picoseconds to durations approaching pulse width available with commercial instruments. We show that the energy cost for SOT switching decreases by more than an order of magnitude in all samples when the pulse duration enters the picosecond range. We project an energy cost of 9 fJ for a 100 x 100 nm 2 ferrimagnetic device. Micromagnetic and macrospin simulations unveil a transition from a non-coherent to a coherent magnetization reversal with a strong modification of the magnetization dynamical trajectories as pulse duration is reduced. Our results cement the potential for high-speed magnetic spin-orbit torque memories and highlights alternative magnetization reversal pathways at fast time scales.
format Preprint
id arxiv_https___arxiv_org_abs_2410_00474
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Energy-efficient picosecond spin-orbit torque magnetization switching in ferro- and ferrimagnetic films
Díaz, Eva
Anadón, Alberto
Olleros-Rodríguez, Pablo
Singh, Harjinder
Damas, Héloïse
Perna, Paolo
Morassi, Martina
Lemaître, Aristide
Hehn, Michel
Gorchon, Jon
Materials Science
Electrical current pulses can be used to manipulate magnetization efficiently via spin-orbit torques (SOTs). Pulse durations as short as a few picoseconds have been used to switch the magnetization of ferromagnetic films, reaching the THz regime. However, little is known about the reversal mechanisms and energy requirements in the ultrafast switching regime. In this work, we quantify the energy cost for magnetization reversal over 7 orders of magnitude in pulse duration, in both ferromagnetic and ferrimagnetic samples, bridging quasi-static spintronics and femtomagnetism. To this end, we develop a method to stretch picosecond pulses generated by a photoconductive switch by an order of magnitude. Thereby, we can create current pulses from picoseconds to durations approaching pulse width available with commercial instruments. We show that the energy cost for SOT switching decreases by more than an order of magnitude in all samples when the pulse duration enters the picosecond range. We project an energy cost of 9 fJ for a 100 x 100 nm 2 ferrimagnetic device. Micromagnetic and macrospin simulations unveil a transition from a non-coherent to a coherent magnetization reversal with a strong modification of the magnetization dynamical trajectories as pulse duration is reduced. Our results cement the potential for high-speed magnetic spin-orbit torque memories and highlights alternative magnetization reversal pathways at fast time scales.
title Energy-efficient picosecond spin-orbit torque magnetization switching in ferro- and ferrimagnetic films
topic Materials Science
url https://arxiv.org/abs/2410.00474