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Sie sind hier:» Universität » SFB 1083 » News » News » 19.02.2021: Tracing orbital images on ultrafast time scales – Publication by B6 (Höfer/Wallauer) and A12 (Tautz/Bocquet/Kumpf) in Science

19.02.2021

19.02.2021: Tracing orbital images on ultrafast time scales – Publication by B6 (Höfer/Wallauer) and A12 (Tautz/Bocquet/Kumpf) in Science

Robert Wallauer and coworkers combined a high harmonic laser source with an electron momentum microscope to record orbital images of the charge transfer at an organic/metal interface with femtosecond time resolution.

B6_A12_Figure1
Excitation scheme for time-resolved photoemission orbital tomography. (b) Measured LUMO momentum maps for three selected delay times between pump and probe pulse. (c) Scheme of intramolecular and substrate-to-molecule excitation pathways. The LUMO pattern of the 0° molecule in (b) is seen to light up faster due to resonant HOMO-LUMO excitation than that of the 90° populated across the CuO Interface.

The microscopic charge-transfer dynamics across molecular interfaces is reflected in the population of electronic orbitals. These were, for the first time, directly monitored with ultrafast time resolution in a joint experimental effort of B6 (Höfer/Wallauer) in Marburg and A12 (Tautz/Bocquet/Kumpf) in Jülich. The experiment records the full two-dimensional intensity distribution of photoemitted electrons in momentum space in a femtosecond pump-probe scheme. Real-space electron distributions and photoemission momentum maps, called orbital tomographs, are related by a Fourier transform.

The model interface PTCDA/CuO/Cu(100) exhibits two distinct excitation pathways for the PTCDA molecule. The parallel component of the electric field of the pump pulse makes a direct HOMO-LUMO transition, while the perpendicular component transfers an electron from the metal across the atomically thin CuO spacer into the molecular LUMO. Once excited, the LUMO decays with a lifetime of 250 fs, independent of the excitation pathway.

In the future, the new experimental capability is expected to facilitate the microscopic understanding of charge-transfer and exciton-formation processes at several other classes of organic heterointerfaces with unprecedented detail, including interfaces between 2D semiconductors and layered organic molecular structures.

 

Informational Material

- Joint press release of the universities of Marburg and Graz and the FZ Jülich (available in English and German).
- News, Philipps-Universität Marburg (in German).
- News, Universität Graz, Österreich (in German).

 

Publication

R. Wallauer, M. Raths, K. Stallberg, L. Münster, D. Brandstetter, X. Yang, J. Güdde, P. Puschnig, S. Soubatch, C. Kumpf, F.C. Bocquet, F.S. Tautz, U. Höfer
Tracing orbital images on ultrafast time scales
Science 371 (2021) 1056 DOI:10.1126/science.abf3286


Contact

Prof. Dr. Ulrich Höfer                 
Prof. Dr. Stefan Tautz
Philipps-Universität Marburg
FZ Jülich
SFB 1083, project B6
PGI, Experimental Physics, project A12
Tel.: +49 6421 28-24215
Tel.: +49 (0)2461 61-4561
ulrich.hoefer@physik.uni-marburg.de
s.tautz@fz-juelich.de

Zuletzt aktualisiert: 05.03.2021 · kachels

 
 
 
Philipps-Universität Marburg

Sonderforschungsbereich 1083, Philipps-Universität Marburg, Renthof 5, 35032 Marburg, Germany
Tel. +49 6421 28-24223, Fax +49 6421 28-24218, E-Mail: info@uni-marburg.de

URL dieser Seite: https://www.uni-marburg.de/sfb1083/aktuelles/news/2021-02-19

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