Moritz Hofherr scite author profile

The vision of using light to manipulate electronic and spin excitations in materials on their fundamental time and length scales requires new approaches in experiment and theory to observe and understand these excitations. The ultimate speed limit for all-optical manipulation requires control schemes for which the electronic or magnetic subsystems of the materials are coherently manipulated on the time scale of the laser excitation pulse. In our work, we provide experimental evidence of such a direct, ultrafast, and coherent spin transfer between two magnetic subsystems of an alloy of Fe and Ni. Our experimental findings are fully supported by time-dependent density functional theory simulations and, hence, suggest the possibility of coherently controlling spin dynamics on subfemtosecond time scales, i.e., the birth of the research area of attomagnetism.

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Direct light–induced spin transfer between different elements in a spintronic Heusler material via femtosecond laser excitation

Tengdin

Gentry

Blonsky

et al. 2020

Sci. Adv.

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Heusler compounds are exciting materials for future spintronics applications because they display a wide range of tunable electronic and magnetic interactions. Here, we use a femtosecond laser to directly transfer spin polarization from one element to another in a half-metallic Heusler material, Co2MnGe. This spin transfer initiates as soon as light is incident on the material, demonstrating spatial transfer of angular momentum between neighboring atomic sites on time scales < 10 fs. Using ultrafast high harmonic pulses to simultaneously and independently probe the magnetic state of two elements during laser excitation, we find that the magnetization of Co is enhanced, while that of Mn rapidly quenches. Density functional theory calculations show that the optical excitation directly transfers spin from one magnetic sublattice to another through preferred spin-polarized excitation pathways. This direct manipulation of spins via light provides a path toward spintronic devices that can operate on few-femtosecond or faster time scales.

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Speed and efficiency of femtosecond spin current injection into a nonmagnetic material

et al. 2017

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Efficiency of ultrafast optically induced spin transfer in Heusler compounds

Steil

Walowski

Gerhard

et al. 2020

Phys. Rev. Research

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Induced versus intrinsic magnetic moments in ultrafast magnetization dynamics

et al. 2018

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Moritz Hofherr

Ultrafast optically induced spin transfer in ferromagnetic alloys

Direct light–induced spin transfer between different elements in a spintronic Heusler material via femtosecond laser excitation

Speed and efficiency of femtosecond spin current injection into a nonmagnetic material

Efficiency of ultrafast optically induced spin transfer in Heusler compounds

Induced versus intrinsic magnetic moments in ultrafast magnetization dynamics

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