Influence of yttrium iron garnet thickness and heater opacity on the nonlocal transport of electrically and thermally excited magnons

Publication date

2016-11-23

Authors

Shan, Juan
Cornelissen, Ludo J.
Vlietstra, Nynke
Ben Youssef, Jamal
Kuschel, Timo
Duine, R.A.ISNI 0000000387951716
Van Wees, Bart J.

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Document Type

Article
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Abstract

We studied the nonlocal transport behavior of both electrically and thermally excited magnons in yttrium iron garnet (YIG) as a function of its thickness. For electrically injected magnons, the nonlocal signals decrease monotonically as the YIG thickness increases. For the nonlocal behavior of the thermally generated magnons, or the nonlocal spin Seebeck effect (SSE), we observed a sign reversal which occurs at a certain heater-detector distance, and it is influenced by both the opacity of the YIG/heater interface and the YIG thickness. Our nonlocal SSE results can be qualitatively explained by the bulk-driven SSE mechanism together with the magnon diffusion model. Using a two-dimensional finite element model (2D-FEM), we estimated the bulk spin Seebeck coefficient of YIG at room temperature. The quantitative disagreement between the experimental and modeled results indicates more complex processes going on in addition to magnon diffusion and relaxation, especially close to the contacts.

Keywords

Electronic, Optical and Magnetic Materials, Condensed Matter Physics

Citation

Shan, J, Cornelissen, L J, Vlietstra, N, Ben Youssef, J, Kuschel, T, Duine, R & Van Wees, B J 2016, 'Influence of yttrium iron garnet thickness and heater opacity on the nonlocal transport of electrically and thermally excited magnons', Physical Review B - Condensed Matter and Materials Physics, vol. 94, no. 17, 174437. https://doi.org/10.1103/PhysRevB.94.174437