Preprint

FZJ-2025-03649

http://join2-wiki.gsi.de/foswiki/pub/Main/Artwork/join2_logo100x88.png Multi-Orbital Charge Transfer into Nonplanar Cycloarenes Revealed with CO-Functionalized Tips

Haags, A. (First author)FZJ* ; Reichmann, A. ; Ruan, Z. ; Fan, Q. ; Egger, L. ; Kirschner, H. ; Naumann, T. ; Werner, S. ; Kleykamp, O. ; Martinez-Castro, J.FZJ* ; Lüpke, F.FZJ* ; Bocquet, F. C.FZJ* ; Kumpf, C.FZJ* ; Soubatch, S.FZJ* ; Gottwald, A. ; Koller, G. ; Ramsey, M. G. ; Richter, M. ; Sundermeyer, J. ; Puschnig, P. ; Gottfried, J. M. ; Tautz, F. S.FZJ* ; Wenzel, S. (Corresponding author)Extern*FZJ*

2025
arXiv

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Please use a persistent id in citations: doi:10.48550/ARXIV.2509.00736

Abstract: On-surface synthesis has allowed for the tuneable preparation of numerous molecular systems with variable properties. Recently, we demonstrated the highly selective synthesis of kekulene (>99%) on Cu(111) and isokekulene (92%) on Cu(110) from the same molecular precursor (Ruan et al., Angew. Chem. Int. Ed. 2025, e202509932). Scanning tunneling microscopy with CO-functionalized tips can identify the single molecules on the basis of their geometric structure at a low coverage on Cu(110), but it also detects complex features due to electronic contributions close to the Fermi energy. Here, we investigate the origin of these features by simulating STM images based on a weighted sum of multiple molecular orbitals, for which we employ weights based on the calculated molecular-orbital projected density of states. This allows for an experimental confirmation of charge transfer from the surface into multiple formerly unoccupied molecular orbitals for single molecules of kekulene as well as isokekulene in its two nonplanar adsorption configurations. In comparison, the area-integrating photoemission orbital tomography technique confirms the charge transfer as well as the high selectivity for the formation of a full monolayer of mainly isokekulene on Cu(110). Our STM-based approach is applicable to a wide range of adsorbed molecular systems and specifically also suited for strongly interacting surfaces, nonplanar molecules, and such molecules which can only be prepared at extremely low yields.

Keyword(s): Chemical Physics (physics.chem-ph) ; Materials Science (cond-mat.mtrl-sci) ; FOS: Physical sciences

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Contributing Institute(s):

1. Quantum Nanoscience (PGI-3)

Research Program(s):

1. 5213 - Quantum Nanoscience (POF4-521) (POF4-521)
2. SFB 1083 A12 - Struktur und Anregungen von hetero-epitaktischen Schichtsystemen aus schwach wechselwirkenden 2D-Materialien und molekularen Schichten (A12) (385975694) (385975694)
3. TACY - Tackling the Cyclacene Challenge (101071420) (101071420)
4. DFG project G:(GEPRIS)511561801 - Manipulierung von 2D Supraleitung und Majorana Zuständen auf der Nanoskala (511561801) (511561801)
5. ML4Q - Machine Learning for Quantum (101120240) (101120240)

Appears in the scientific report 2025

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