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FM: Fachverband Funktionsmaterialien

FM 11: Poster Session Functional Materials

FM 11.23: Poster

Dienstag, 10. März 2026, 18:00–20:30, P4

Reversible nanoscale patterning of WTe₂ with a scanning tunneling microscope — •Kevin Hauser^1,2, Danyang Liu¹, Berk Zengin¹, Jens Oppliger¹, Samuel Mañas-Valero⁴, Catherine Witteveen⁵, Fabian O. von Rohr⁵, Jennifer E. Hoffman^2,3, and Fabian D. Natterer¹ — ¹Department of Physics, University of Zurich, Switzerland — ²Department of Physics, Harvard University, Cambridge MA, USA — ³School of Engineering & Applied Sciences, Harvard University, Cambridge MA, USA — ⁴Instituto de Ciencia Molecular, Universitat de València, Spain — ⁵Department of Quantum Matter Physics, University of Geneva, Switzerland

Manipulating the lattice structure of quantum materials that host ferroelectric or Weyl semimetal phases provides a route to control these states on nanometer length scales. Prior experiments on the type-II Weyl semimetal candidate WTe₂ have demonstrated ferroelectric switching on micrometer length scales and transient control of the predicted topological phase via ultrafast excitations. However, both approaches lack the ability to induce persistent, localized distortions on the nanometer scale. In this contribution, we use current pulses applied by a scanning tunneling microscope (STM) to write, move, and erase nanoscale lattice distortions on WTe₂. The resulting lattice distortions consist of picometer-scale in-plane and out-of-plane atomic displacements, accompanied by changes in the local density of states. The in-plane shifts are on the same order of magnitude as expected for ferroelectric switching. These results demonstrate local, reversible control of the lattice structure of WTe₂ on nanometer length scales.

Keywords: STM; WTe2; Ferroelectric switching; weyl semimetal; lattice engineering