Superconducting gap of H3S measured by tunnelling spectroscopy

Du, Feng; Drozdov, Alexander P.; Minkov, Vasily S.; Balakirev, Fedor F.; Kong, Panpan; Smith, G. Alexander; Yan, Jiafeng; Shen, Bin; Gegenwart, Philipp; Eremets, Mikhail I.

Superconducting gap of H3S measured by tunnelling spectroscopy

Feng Du (), Alexander P. Drozdov, Vasily S. Minkov, Fedor F. Balakirev, Panpan Kong, G. Alexander Smith, Jiafeng Yan, Bin Shen, Philipp Gegenwart and Mikhail I. Eremets
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Feng Du: Max Planck Institute for Chemistry
Alexander P. Drozdov: Max Planck Institute for Chemistry
Vasily S. Minkov: Max Planck Institute for Chemistry
Fedor F. Balakirev: Los Alamos National Laboratory
Panpan Kong: Institute of Physics Chinese Academy of Sciences
G. Alexander Smith: Los Alamos National Laboratory
Jiafeng Yan: Hanyang University
Bin Shen: University of Augsburg
Philipp Gegenwart: University of Augsburg
Mikhail I. Eremets: Max Planck Institute for Chemistry

Nature, 2025, vol. 641, issue 8063, 619-624

Abstract: Abstract Several hydrogen-rich superconductors have been found to show unprecedentedly high critical temperatures1–4, stimulating investigations into the nature of the superconductivity in these materials. Although their macroscopic superconducting properties are established1,5–7, microscopic insights into the pairing mechanism remains unclear. Here we characterize the superconducting gap structure in the high-temperature superconductor H3S and its deuterium counterpart D3S by performing tunnelling spectroscopy measurements. The tunnelling spectra reveal that H3S and D3S both have a fully gapped structure, which could be well described by a single s-wave Dynes model, with gap values 2Δ of approximately 60 meV and 44 meV, respectively. Furthermore, we observed gap features of another likely H-depleted HxS superconducting phase in a poorly synthesized hydrogen sulfide sample. Our work offers direct experimental evidence for superconductivity in the hydrogen-rich superconductor H3S from a microscopic perspective. It validates the phonon-mediated mechanism of superconducting pairing and provides a foundation for further understanding the origins of high-temperature superconductivity in hydrogen-rich compounds.

Date: 2025
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DOI: 10.1038/s41586-025-08895-2

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