Electric-Field Control of Zero-Dimensional Topological States in Ultranarrow Germanene Nanoribbons

Lumen Eek; Esra D. Van 'T Westende; Dennis J. Klaassen; Harold J.W. Zandvliet; Pantelis Bampoulis; Cristiane Morais Smith

doi:10.1103/jx2x-fb5b

Electric-Field Control of Zero-Dimensional Topological States in Ultranarrow Germanene Nanoribbons

Lumen Eek
, Esra D. Van 'T Westende
, Dennis J. Klaassen
, Harold J.W. Zandvliet
, Pantelis Bampoulis^*
, Cristiane Morais Smith^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Reversible, all-electric control of symmetry-protected zero-dimensional modes has been a long-standing goal. In buckled honeycomb lattices, a perpendicular field couples to the staggered sublattice potential providing the required handle. We combine scanning tunneling microscopy and tight-binding theory to switch zero-dimensional topological end states reversibly on and off in ultranarrow germanene nanoribbons by tuning the electric field in the tunnel junction. Increasing the field switches off the end modes of topological two-hexagon-wide ribbons, while the same field switches on zero-dimensional states in initially trivial three- and four-hexagon-wide ribbons. This atomic scale platform realizes a proof of principle for a zero-dimensional topological field effect device, opening a path for ultrasmall memory, controllable qubits, and neuromorphic architectures.

Original language	English
Article number	206601
Number of pages	8
Journal	Physical review letters
Volume	135
Issue number	20
Early online date	12 Nov 2025
DOIs	https://doi.org/10.1103/jx2x-fb5b
Publication status	Published - 14 Nov 2025

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abstract = "Reversible, all-electric control of symmetry-protected zero-dimensional modes has been a long-standing goal. In buckled honeycomb lattices, a perpendicular field couples to the staggered sublattice potential providing the required handle. We combine scanning tunneling microscopy and tight-binding theory to switch zero-dimensional topological end states reversibly on and off in ultranarrow germanene nanoribbons by tuning the electric field in the tunnel junction. Increasing the field switches off the end modes of topological two-hexagon-wide ribbons, while the same field switches on zero-dimensional states in initially trivial three- and four-hexagon-wide ribbons. This atomic scale platform realizes a proof of principle for a zero-dimensional topological field effect device, opening a path for ultrasmall memory, controllable qubits, and neuromorphic architectures.",

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AU - Klaassen, Dennis J.

AU - Zandvliet, Harold J.W.

AU - Bampoulis, Pantelis

AU - Morais Smith, Cristiane

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Electric-Field Control of Zero-Dimensional Topological States in Ultranarrow Germanene Nanoribbons

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