Gate-Tunable Helical Currents in Commensurate Topological Insulator/Graphene Heterostructures
ORAL
Abstract
Interfaces between graphene and the topological insulator Bi2Te2Se feature a lattice-matched, commensurate stacking, where proximity effects have been predicted to impart an anisotropic and electronically tunable spin texture [1]. Here, we demonstrate the growth of such expitaxial and commensurate interfaces, we characterize their interfacial symmetries by optical spectroscopies, and we adress the gate-tunable spin-orbit poximity by polarization resolved photocurrent spectroscopy. As a main finding, we demonstrate a circular photogalvanic effect which is drastically enhanced at the Dirac point of the proximitized graphene. We attribute the gate-tunability to the proximity-induced interfacial spin structure, which could be exploited, for example, in spin filters [2].
[1] Song et al. Nano Lett. 18, 2033 (2018)
[2] Kiemle et al. ACS Nano 16, 12338 (2022).
[1] Song et al. Nano Lett. 18, 2033 (2018)
[2] Kiemle et al. ACS Nano 16, 12338 (2022).
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Publication: J. Kiemle, L. Powalla, K. Polyudov, L. Gulati, M. Singh, A. Holleitner, M. Burghard, C. Kastl, Gate-Tunable Helical Currents in Commensurate Topological Insulator/Graphene Heterostructures, ACS Nano 16, 12338 (2022).
Presenters
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Christoph Kastl
TU Munich
Authors
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Christoph Kastl
TU Munich
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Alexander Holleitner
TU Munich, Technical University of Munich
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Jonas Kiemle
Technical University of Munich
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Marko Burghard
Max-Planck-Institute for Solid State Research Stuttgart
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Lukas Powalla
Max-Planck-Institue for Solid State Research Stuttgart