Backscattering in topological edge states despite time-reversal symmetry

Erhardt, Jonas; Iannetti, Mattia; Dominguez, Fernando; Hankiewicz, Ewelina M.; Trauzettel, Björn; Profeta, Gianni; Sante, Domenico; Sangiovanni, Giorgio; Moser, Simon; Claessen, Ralph

Backscattering in topological edge states despite time-reversal symmetry

Jonas Erhardt, Mattia Iannetti, Fernando Dominguez, Ewelina M. Hankiewicz, Björn Trauzettel, Gianni Profeta, Domenico Sante, Giorgio Sangiovanni, Simon Moser and Ralph Claessen ()
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Jonas Erhardt: Universität Würzburg
Mattia Iannetti: University of L’Aquila
Fernando Dominguez: Universität Würzburg
Ewelina M. Hankiewicz: Universität Würzburg
Björn Trauzettel: Universität Würzburg
Gianni Profeta: University of L’Aquila
Domenico Sante: University of Bologna
Giorgio Sangiovanni: Universität Würzburg
Simon Moser: Universität Würzburg
Ralph Claessen: Universität Würzburg

Nature Communications, 2025, vol. 16, issue 1, 1-7

Abstract: Abstract Spin-momentum-locked edge states of quantum spin Hall insulators provide a compelling platform for spintronic applications, owing to their intrinsic protection against backscattering from non-magnetic disorder. This protection emerges from time-reversal symmetry, which pairs Kramers partners of helical edge modes with opposite spin and momentum, thereby strictly forbidding elastic single-particle backscattering within the pair. Yet, contrary to the idealized notion of linear edge bands, the non-monotonic dispersions of realistic materials can host multiple Kramers pairs, reintroducing backscattering channels between them without violating time-reversal symmetry. Here, we investigate inter-Kramers pair backscattering in the non-linear edge bands of the quantum spin Hall insulator indenene, highlighting a critical aspect of edge state stability. Using quasiparticle interference in scanning tunneling spectroscopy – a direct probe of backscattering – we observe intra-band coupling between different Kramers pairs, while energy regions with only a single Kramers pair remain strictly protected. Supported by theoretical analysis, our findings provide an unprecedented experimental demonstration of edge state backscattering fully consistent with their underlying topological protection. This insight has profound implications for numerous quantum spin Hall insulator candidates, emphasizing that the mere presence of gap-traversing edge modes does not inherently guarantee their protection against backscattering.

Date: 2025
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DOI: 10.1038/s41467-025-63572-2

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