Quantum twisting microscopy of phonons in twisted bilayer graphene

Birkbeck, J.; Xiao, J.; Inbar, A.; Taniguchi, T.; Watanabe, K.; Berg, E.; Glazman, L.; Guinea, F.; Oppen, F.; Ilani, S.

Quantum twisting microscopy of phonons in twisted bilayer graphene

J. Birkbeck, J. Xiao, A. Inbar, T. Taniguchi, K. Watanabe, E. Berg, L. Glazman, F. Guinea, F. Oppen and S. Ilani ()
Additional contact information
J. Birkbeck: Weizmann Institute of Science
J. Xiao: Weizmann Institute of Science
A. Inbar: Weizmann Institute of Science
T. Taniguchi: National Institute for Materials Science
K. Watanabe: National Institute for Materials Science
E. Berg: Weizmann Institute of Science
L. Glazman: Yale University
F. Guinea: IMDEA Nanoscience
F. Oppen: Freie Universität Berlin
S. Ilani: Weizmann Institute of Science

Nature, 2025, vol. 641, issue 8062, 345-351

Abstract: Abstract The coupling between electrons and phonons is one of the fundamental interactions in solids, underpinning a wide range of phenomena, such as resistivity, heat conductivity and superconductivity. However, direct measurements of this coupling for individual phonon modes remain a substantial challenge. In this work, we introduce a new technique for mapping phonon dispersions and electron–phonon coupling (EPC) in van der Waals (vdW) materials. By generalizing the quantum twisting microscope1 (QTM) to cryogenic temperatures, we demonstrate its capability to map not only electronic dispersions through elastic momentum-conserving tunnelling but also phononic dispersions through inelastic momentum-conserving tunnelling. Crucially, the inelastic tunnelling strength provides a direct and quantitative measure of the momentum and mode-resolved EPC. We use this technique to measure the phonon spectrum and EPC of twisted bilayer graphene (TBG) with twist angles larger than 6°. Notably, we find that, unlike standard acoustic phonons, whose coupling to electrons diminishes as their momentum tends to zero, TBG exhibits a low-energy mode whose coupling increases with decreasing twist angle. We show that this unusual coupling arises from the modulation of the interlayer tunnelling by a layer-antisymmetric ‘phason’ mode of the moiré system. The technique demonstrated here opens the way for examining a large variety of other neutral collective modes that couple to electronic tunnelling, including plasmons2, magnons3 and spinons4 in quantum materials.

Date: 2025
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DOI: 10.1038/s41586-025-08881-8

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