Author
Listed:
- Simon Aeschlimann
(Johannes Gutenberg University Mainz
Graduate School Materials Science in Mainz)
- Sebastian V. Bauer
(Johannes Gutenberg University Mainz)
- Maximilian Vogtland
(Bielefeld University)
- Benjamin Stadtmüller
(University of Kaiserslautern)
- Martin Aeschlimann
(University of Kaiserslautern)
- Andrea Floris
(University of Lincoln)
- Ralf Bechstein
(Bielefeld University)
- Angelika Kühnle
(Bielefeld University)
Abstract
Controlling self-assembled nanostructures on bulk insulators at room temperature is crucial towards the fabrication of future molecular devices, e.g., in the field of nanoelectronics, catalysis and sensor applications. However, at temperatures realistic for operation anchoring individual molecules on electrically insulating support surfaces remains a big challenge. Here, we present the formation of an ordered array of single anchored molecules, dimolybdenum tetraacetate, on the (10.4) plane of calcite (CaCO3). Based on our combined study of atomic force microscopy measurements and density functional theory calculations, we show that the molecules neither diffuse nor rotate at room temperature. The strong anchoring is explained by electrostatic interaction of an ideally size-matched molecule. Especially at high coverage, a hard-sphere repulsion of the molecules and the confinement at the calcite surface drives the molecules to form locally ordered arrays, which is conceptually different from attractive linkers as used in metal-organic frameworks. Our work demonstrates that tailoring the molecule-surface interaction opens up the possibility for anchoring individual metal-complexing molecules into ordered arrays.
Suggested Citation
Simon Aeschlimann & Sebastian V. Bauer & Maximilian Vogtland & Benjamin Stadtmüller & Martin Aeschlimann & Andrea Floris & Ralf Bechstein & Angelika Kühnle, 2020.
"Creating a regular array of metal-complexing molecules on an insulator surface at room temperature,"
Nature Communications, Nature, vol. 11(1), pages 1-8, December.
Handle:
RePEc:nat:natcom:v:11:y:2020:i:1:d:10.1038_s41467-020-20189-x
DOI: 10.1038/s41467-020-20189-x
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