6533b837fe1ef96bd12a3495

RESEARCH PRODUCT

Magnon mode selective spin transport in compensated ferrimagnets

Kathrin GanzhornMatthias AlthammerJoel CramerMathias KläuiFrancesco Della ColettaHans HueblHans HueblEr-jia GuoEr-jia GuoSebastian T. B. GoennenweinRudolf GrossRudolf GrossYurii IvanovYurii IvanovYurii IvanovJurgen KoselStephan GeprägsAndreas Kehlberger

subject

Materials scienceFOS: Physical sciencesBioengineering02 engineering and technology01 natural sciencesMetalCondensed Matter::Materials ScienceFerrimagnetism0103 physical sciencesThermoelectric effectThermalGeneral Materials Science010306 general physicsCondensed Matter - Materials ScienceCondensed matter physicsSpin polarizationMechanical EngineeringMagnonBilayerMaterials Science (cond-mat.mtrl-sci)General Chemistry021001 nanoscience & nanotechnologyCondensed Matter Physicsvisual_artvisual_art.visual_art_mediumCondensed Matter::Strongly Correlated Electrons0210 nano-technologyVoltage

description

We investigate the generation of magnonic thermal spin currents and their mode selective spin transport across interfaces in insulating, compensated ferrimagnet/normal metal bilayer systems. The spin Seebeck effect signal exhibits a non-monotonic temperature dependence with two sign changes of the detected voltage signals. Using different ferrimagnetic garnets, we demonstrate the universality of the observed complex temperature dependence of the spin Seebeck effect. To understand its origin, we systematically vary the interface between the ferrimagnetic garnet and the metallic layer, and by using different metal layers we establish that interface effects play a dominating role. They do not only modify the magnitude of the spin Seebeck effect signal but in particular also alter its temperature dependence. By varying the temperature, we can select the dominating magnon mode and we analyze our results to reveal the mode selective interface transmission probabilities for different magnon modes and interfaces. The comparison of selected systems reveals semi-quantitative details of the interfacial coupling depending on the materials involved, supported by the obtained field dependence of the signal.

yearjournalcountryeditionlanguage
2017-03-09
https://dx.doi.org/10.48550/arxiv.1703.03218