High-harmonic generation in spin and charge current pumping at ferromagnetic or antiferromagnetic resonance in the presence of spin-orbit coupling
Abstract
One of the cornerstone effects in spintronics is spin pumping by dynamical magnetization that is steadily precessing (around, e.g., the z-axis) with frequency ω0, due to absorption of low-power microwaves of frequency ω0 under the resonance conditions and in the absence of any applied bias voltage. The two-decades-old "standard model" of this effect, based on the scattering theory of adiabatic quantum pumping, predicts that component ISz of spin current vector ( ISx(t),ISy(t),ISz ) ω0 is time-independent while ISx(t) and ISy(t) oscillate harmonically in time with a single frequency ω0; whereas pumped charge current is zero I 0 in the same adiabatic ω0 limit. Here we employ more general than "standard model" approaches, time-dependent nonequilibrium Green's function (NEGF) and Floquet-NEGF, to predict unforeseen features of spin pumping -- precessing localized magnetic moments within ferromagnetic metal (FM) or antiferromagnetic metal (AFM), whose conduction electrons are exposed to spin-orbit coupling (SOC) of either intrinsic or proximity origin, will pump both spin ISα(t) and charge I(t) currents. All four of these functions harmonically oscillate in time at both even an odd integer multiples Nω0 of the driving frequency ω0. The cutoff order of such high-harmonics increases with SOC strength, reaching Nmax 11 in the chosen-for-demonstration one-dimensional FM or AFM models. Higher cutoff Nmax 25 can be achieved in realistic two-dimensional (2D) FM models defined on the honeycomb lattice, where we provide prescription on how to realize them using 2D magnets and their heterostructures.
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