Distinct Quantum States in Topological Insulator Surfaces of Nanowires and Nanoribbons of Bismuth Selenide (Bi2Se3)

Distinct Quantum States in Topological Insulator Surfaces of Nanowires and Nanoribbons of Bismuth Selenide (Bi2Se3)

Topological insulators (TIs) exhibit unconventional quantum phases that can be tuned by external quantum confinements. The geometry of the surface of 3D TIs plays a crucial role. For example, the geometrical crossover from 2D surfaces to a 1D cylinder results in a novel state with a Spin‐Berry Phase...

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Bibliographic Details
Published in:Advanced materials interfaces Vol. 11; no. 16
Main Authors: Nweze, Christian, Glier, Tomke E., Rerrer, Mika, Heek, Malte, Scheitz, Sarah, Akinsinde, Lewis O., Kohlmann, Niklas, Kienle, Lorenz, Huang, Yalan, Parak, Wolfgang J., Huse, Nils, Rübhausen, Michael
Format: Journal Article
Language:English
Published: Weinheim John Wiley & Sons, Inc 01-06-2024
Wiley-VCH
Subjects:
Bismuth
geometry 1D nanostructures
nanoribbon
Nanoribbons
nanowire
Nanowires
quantum confinement
Quantum mechanics
Raman spectra
Relativistic effects
Spatial resolution
spin Berry phase
surface‐enhanced Raman scattering
topological insulator
Topological insulators
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Summary:Topological insulators (TIs) exhibit unconventional quantum phases that can be tuned by external quantum confinements. The geometry of the surface of 3D TIs plays a crucial role. For example, the geometrical crossover from 2D surfaces to a 1D cylinder results in a novel state with a Spin‐Berry Phase (SBP). Surface‐Enhanced Raman Scattering (SERS) with a sub‐micron spatial resolution is utilized to study the quantum‐confinement effects of quasi‐relativistic electrons along the perimeter of the circular bismuth selenide (Bi2Se3) nanowires. The presence of diameter‐dependent SERS in nanowires can be attributed to the self‐interference effect of the electronic wave‐function along the circumferential direction of the TI nanowires. Nanoribbons with rectangular cross‐section do not show this effect. Further gold nanoparticles are applied as plasmonic SERS sensors attached to the distinct topological surface states to manipulate quasi‐relativistic surface states of nanoribbons and nanowires. This technique enables to discriminate between different geometries of TI surface states and also opens a novel pathway to probe the quantum properties of topological surface states. With the aid of nanoscopic Raman spectroscopy, the geometrical crossover is shown from a 2D to a 1D behavior in Bi2Se3 nanowires. AuNP attached to the TI surface is utilized to discriminate spin densities and spin confinements in nanoribbons from that in nanowires.
ISSN:2196-7350
2196-7350
DOI:10.1002/admi.202301109