Spin pumping from a ferromagnet into a hopping insulator: Role of resonant absorption of magnons

Abstract: Motivated by recent experiments on spin pumping from a ferromagnet into organic materials in which the charge transport is due to hopping, we study theoretically the generation and propagation of spin current in a hopping insulator. Unlike metals, the spin polarization at the boundary with ferromagnet is created as a result of magnon absorption within pairs of localized states and it spreads following the current-currying resistor network (although the charge current is absent). We consider a classic resonant … Show more

“…The emerging field of "quantum spintronics" seeks to engineer and manipulate single coherent spin systems for the sake of quantum-enhanced sensing/imaging technologies and quantum computing [1]. Defect spins in an insulating region between a ferromagnetic metal and a nonmagnetic conductor produce an array of coherent spin-dependent phenomena, including defect-associated spin pumping [2][3][4], thermal spin transport [5], and small-field magnetoresistance under electrical bias [6][7][8]. Individual spin-coherent defects have even been electrically detected in precisely-designed junctions [9,10].…”

Theory of spin-coherent electrical transport through a defect spin state in a metal/insulator/ferromagnet tunnel junction undergoing ferromagnetic resonance

“…The emerging field of "quantum spintronics" seeks to engineer and manipulate single coherent spin systems for the sake of quantum-enhanced sensing/imaging technologies and quantum computing [1]. Defect spins in an insulating region between a ferromagnetic metal and a nonmagnetic conductor produce an array of coherent spin-dependent phenomena, including defect-associated spin pumping [2][3][4], thermal spin transport [5], and small-field magnetoresistance under electrical bias [6][7][8]. Individual spin-coherent defects have even been electrically detected in precisely-designed junctions [9,10].…”

Theory of spin-coherent electrical transport through a defect spin state in a metal/insulator/ferromagnet tunnel junction undergoing ferromagnetic resonance

“…As the magnitude of the ISHE response scales linearly with the strength of the MW radiation field [3][4][5][6][7][8], quantitative ISHE experiments which, for instance, are needed to test fundamental theories of charge free spin-injection into organic semiconductors [9] or the nature of spin transport in the latter [10], require a precise knowledge of the strength of the MW radiation amplitude B 1 . Most studies involving ISHE experiments derive B 1 from estimates that are based on the MW power applied to the resonator or waveguide structure.…”

Quantitative inverse spin Hall effect detection via precise control of the driving-field amplitude

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