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  Quantitative sampling of atomic-scale electromagnetic waveforms

Peller, D., Roelcke, C., Kastner, L. Z., Buchner, T., Neef, A., Hayes, J., et al. (2021). Quantitative sampling of atomic-scale electromagnetic waveforms. Nature Photonics, 15(2), 143-147. doi:10.1038/s41566-020-00720-8.

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Supplementary Information (pdf): Supplementary Note 1 and Figs. 1 and 2. | Supplementary Video 1 (mp4): Simulated temporal evolution of the Hartree potential comparing the set-up with molecule in the junction and the free junction. Video showing the vertical cross-section of the Hartree potential, similar to Fig. 4a,b, as it evolves over time when driven by an external waveform. Locally, the calculated Hartree potential without the molecule (left panel) and including the molecule in the junction (right panel) vary strongly. Every frame corresponds to a time step of 215 as. The colour scale indicates the Hartree potential in electronvolts. | Supplementary Video 2 (mp4): Simulated temporal evolution of the Hartree potential comparing two different tip orientations. Video showing the vertical cross-section of the Hartree potential as in Supplementary Video 1 (same time step per frame). Comparing a tilted tip configuration (left panel) with a symmetric geometry (right panel), we obtain very similar spatial distributions of the potential in the vicinity of the molecule, causing similar near-field profiles. Hence the near-field is not strongly dependent on the tip symmetry or orientation. The colour scale indicates the Hartree potential in electronvolts.
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https://dx.doi.org/10.1038/s41566-020-00720-8 (Verlagsversion)
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https://dx.doi.org/10.1038/s41566-020-00753-z (Ergänzendes Material)
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News & Views article "Waveform sampling on an atomic scale" by Jun Takeda & Ikufumi Katayama
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 Urheber:
Peller, D.1, Autor
Roelcke, C.1, Autor
Kastner, L. Z.1, Autor
Buchner, T.1, Autor
Neef, A.1, Autor
Hayes, J.1, Autor
Bonafé, F.2, Autor           
Sidler, D.2, Autor           
Ruggenthaler, M.2, Autor           
Rubio, A.2, 3, 4, Autor           
Huber, R.1, Autor
Repp, J.1, Autor
Affiliations:
1Department of Physics, University of Regensburg, ou_persistent22              
2Theory Group, Theory Department, Max Planck Institute for the Structure and Dynamics of Matter, Max Planck Society, ou_2266715              
3Center for Computational Quantum Physics, Simons Foundation Flatiron Institute, ou_persistent22              
4Universidad del País Vasco, UPV/EHU, San Sebastián, ou_persistent22              

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 Zusammenfassung: Tailored nanostructures can confine electromagnetic waveforms in extremely sub-wavelength volumes, opening new avenues in lightwave sensing and control down to sub-molecular resolution. Atomic light–matter interaction depends critically on the absolute strength and the precise time evolution of the near field, which may be strongly influenced by quantum-mechanical effects. However, measuring atom-scale field transients has remained out of reach. Here we introduce quantitative atomic-scale waveform sampling in lightwave scanning tunnelling microscopy to resolve a tip-confined near-field transient. Our parameter-free calibration employs a single-molecule switch as an atomic-scale voltage standard. Although salient features of the far-to-near-field transfer follow classical electrodynamics, we develop a comprehensive understanding of the atomic-scale waveforms with time-dependent density functional theory. The simulations validate our calibration and confirm that single-electron tunnelling ensures minimal back-action of the measurement process on the electromagnetic fields. Our observations access an uncharted domain of nano-opto-electronics where local quantum dynamics determine femtosecond atomic near fields.

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Sprache(n): eng - English
 Datum: 2020-04-012020-10-152020-11-162021-02
 Publikationsstatus: Erschienen
 Seiten: 5
 Ort, Verlag, Ausgabe: -
 Inhaltsverzeichnis: -
 Art der Begutachtung: Expertenbegutachtung
 Identifikatoren: DOI: 10.1038/s41566-020-00720-8
 Art des Abschluß: -

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Grant ID : 895747
Förderprogramm : Horizon 2020 (H2020)
Förderorganisation : European Commission (EC)
Projektname : We thank C. Meineke, A. Pöllmann, C. Rohrer and M. Furthmeier for assistance and F. Evers, H. Appel and S. Ohlman for discussions. We acknowledge financial support from the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) through Project-ID 314695032—SFB 1277 (Subproject B02), Research Grants HU1598/3 and HU1598/8, the Cluster of Excellence ‘Advanced Imaging of Matter’ (AIM, EXC 2056, ID 390715994) and from Grupos Consolidados (IT1249-19), the European Research Council (ERC-2015-AdG694097), the European Union’s Horizon 2020 research and innovation programme under the Marie Skłodowska-Curie grant agreement no. 895747 and the Flatiron Institute, a division of the Simons Foundation.
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Titel: Nature Photonics
Genre der Quelle: Zeitschrift
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Ort, Verlag, Ausgabe: London [u.a.] : Nature Publ. Group
Seiten: - Band / Heft: 15 (2) Artikelnummer: - Start- / Endseite: 143 - 147 Identifikator: Anderer: 1749-4885
Anderer: 1749-4893
CoNE: https://pure.mpg.de/cone/journals/resource/1000000000240270