Yonghe Sun scite author profile

Strong damping enhancement in nm-thick yttrium iron garnet (YIG) films due to Pt capping layers was observed. This damping is substantially larger than the expected damping due to conventional spin pumping, is accompanied by a shift in the ferromagnetic resonance field, and can be suppressed by the use of a Cu spacer in between the YIG and Pt films. The data indicate that such damping may originate from the ferromagnetic ordering in Pt atomic layers near the YIG/Pt interface and the dynamic exchange coupling between the ordered Pt spins and the spins in the YIG film.

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Growth and ferromagnetic resonance properties of nanometer-thick yttrium iron garnet films

Sun¹,

Song²,

Chang³

et al. 2012

234

128

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Growth of nm-thick yttrium iron garnet films and ferromagnetic resonance (FMR) linewidth properties in the films are reported. The films were grown on gadolinium gallium garnet substrates by pulsed laser deposition (PLD). Films in the 5–35 nm thickness range showed a (111) orientation and a surface roughness between 0.1 and 0.3 nm. The 10 nm films showed a 10 GHz FMR linewidth of about 6 Oe and a damping constant of 3.2 × 10−4. The FMR linewidth increases with both the surface roughness and the surface Fe deficiency. Thicker films exhibit a smaller FMR linewidth and a lower damping constant.

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Enhanced spin pumping at yttrium iron garnet/Au interfaces

Burrowes¹,

Heinrich²,

Kardasz³

et al. 2012

167

108

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Spin injection across the ferrimagnetic insulator yttrium iron garnet (YIG)/normal metal Au interface was studied using ferromagnetic resonance. The spin mixing conductance was determined by comparing the Gilbert damping parameter α in YIG/Au and YIG/Au/Fe heterostructures. The main purpose of this study was to correlate the spin pumping efficiency with chemical modifications of the YIG film surface using in situ etching and deposition techniques. By means of Ar+ ion beam etching, one is able to increase the spin mixing conductance at the YIG/Au interface by a factor of 5 compared to the untreated YIG/Au interface.

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Control of Spin Waves in a Thin Film Ferromagnetic Insulator through Interfacial Spin Scattering

et al. 2011

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Control of spin waves in a ferrite thin film via interfacial spin scattering was demonstrated. The experiments used a 4.6 μm-thick yttrium iron garnet (YIG) film strip with a 20-nm thick Pt capping layer. A dc current pulse was applied to the Pt layer and produced a spin current across the Pt thickness. As the spin current scatters off the YIG surface, it can either amplify or attenuate spin-wave pulses that travel in the YIG strip, depending on the current or field configuration. The spin scattering also affects the saturation behavior of high-power spin waves.

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Yonghe Sun

Spin Pumping at the Magnetic Insulator (YIG)/Normal Metal (Au) Interfaces

Damping in Yttrium Iron Garnet Nanoscale Films Capped by Platinum

Growth and ferromagnetic resonance properties of nanometer-thick yttrium iron garnet films

Enhanced spin pumping at yttrium iron garnet/Au interfaces

Control of Spin Waves in a Thin Film Ferromagnetic Insulator through Interfacial Spin Scattering

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