Direct measurement and modulation of single-molecule coordinative bonding forces in a transition metal complex
Journal article, 2013

Coordination chemistry has been a consistently active branch of chemistry since Werner’s seminal theory of coordination compounds inaugurated in 1893, with the central focus on transition metal complexes. However, control and measurement of metal–ligand interactions at the single-molecule level remain a daunting challenge. Here we demonstrate an interdisciplinary and systematic approach that enables measurement and modulation of the coordinative bonding forces in a transition metal complex. Terpyridine is derived with a thiol linker, facilitating covalent attachment of this ligand on both gold substrate surfaces and gold-coated atomic force microscopy tips. The coordination and bond breaking between terpyridine and osmium are followed in situ by electrochemically controlled atomic force microscopy at the single-molecule level. The redox state of the central metal atom is found to have a significant impact on the metal–ligand interactions. The present approach represents a major advancement in unravelling the nature of metal–ligand interactions and could have broad implications in coordination chemistry.

Author

Xian Hao

Technical University of Denmark (DTU)

Chinese Academy of Sciences

Nan Zhu

Technical University of Denmark (DTU)

Tina Gschneidtner

Chalmers, Chemical and Biological Engineering, Polymer Technology

Elvar Ö. Jönsson

Technical University of Denmark (DTU)

Jingdong Zhang

Technical University of Denmark (DTU)

Kasper Moth-Poulsen

Chalmers, Chemical and Biological Engineering, Polymer Technology

Hongda Wang

Chinese Academy of Sciences

Kristian S. Thygesen

Technical University of Denmark (DTU)

K. W. Jacobsen

Technical University of Denmark (DTU)

Jens Ulstrup

Technical University of Denmark (DTU)

Qijin Chi

Technical University of Denmark (DTU)

Nature Communications

2041-1723 (ISSN) 20411723 (eISSN)

Vol. 4 2121

Subject Categories

Inorganic Chemistry

Nano Technology

DOI

10.1038/ncomms3121

More information

Latest update

4/5/2022 7