Origin of Rashba-splitting in the quantized subbands at Bi2Se3 surface

We study the band structure of the \(\text{Bi}_2\text{Se}_3\) topological insulator (111) surface using angle-resolved photoemission spectroscopy. We examine the situation where two sets of quantized subbands exhibiting different Rashba spin-splitting are created via bending of the conduction (CB) a...

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Bibliographic Details
Published in:arXiv.org 2014-03
Main Authors: Benia, H M, Yaresko, A, Schnyder, A P, Henk, J, Lin, C T, Kern, K, Ast, C R
Format: Article
Language:English
Subjects:
Admixtures
Band structure
Band structure of solids
First principles
Photoelectric emission
Potential gradient
Spin-orbit interactions
Splitting
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Summary:We study the band structure of the \(\text{Bi}_2\text{Se}_3\) topological insulator (111) surface using angle-resolved photoemission spectroscopy. We examine the situation where two sets of quantized subbands exhibiting different Rashba spin-splitting are created via bending of the conduction (CB) and the valence (VB) bands at the surface. While the CB subbands are strongly Rashba spin-split, the VB subbands do not exhibit clear spin-splitting. We find that CB and VB experience similar band bending magnitudes, which means, a spin-splitting discrepancy due to different surface potential gradients can be excluded. On the other hand, by comparing the experimental band structure to first principles LMTO band structure calculations, we find that the strongly spin-orbit coupled Bi 6\(p\) orbitals dominate the orbital character of CB, whereas their admixture to VB is rather small. The spin-splitting discrepancy is, therefore, traced back to the difference in spin-orbit coupling between CB and VB in the respective subbands' regions.
ISSN:2331-8422
DOI:10.48550/arxiv.1307.7384