Single-molecule optomechanical cycle

Thorsten Hugel; Nolan B Holland; Anna Cattani; Luis Moroder; Markus Seitz; Hermann E. Gaub

doi:10.1126/science.1069856

Single-molecule optomechanical cycle

Thorsten Hugel
, Nolan B Holland
, Anna Cattani
, Luis Moroder
, Markus Seitz
, Hermann E. Gaub

Chemical and Biomedical Engineering

Ludwig-Maximilians Universitat

Research output: Contribution to journal › Article › peer-review

789 Scopus citations

Abstract

Light-powered molecular machines are conjectured to be essential constituents of future nanoscale devices. As a model for such systems, we have synthesized a polymer of bistable photosensitive azobenzenes. Individual polymers were investigated by single-molecule force spectroscopy in combination with optical excitation in total internal reflection. We were able to optically lengthen and contract individual polymers by switching the azo groups between their trans and cis configurations. The polymer was found to contract against an external force acting along the polymer backbone, thus delivering mechanical work. As a proof of principle, the polymer was operated in a periodic mode, demonstrating for the first time optomechanical energy conversion in a single-molecule device.

Original language	English
Pages (from-to)	1103-1106
Number of pages	4
Journal	Science
Volume	296
Issue number	5570
DOIs	https://doi.org/10.1126/science.1069856
State	Published - May 10 2002

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AB - Light-powered molecular machines are conjectured to be essential constituents of future nanoscale devices. As a model for such systems, we have synthesized a polymer of bistable photosensitive azobenzenes. Individual polymers were investigated by single-molecule force spectroscopy in combination with optical excitation in total internal reflection. We were able to optically lengthen and contract individual polymers by switching the azo groups between their trans and cis configurations. The polymer was found to contract against an external force acting along the polymer backbone, thus delivering mechanical work. As a proof of principle, the polymer was operated in a periodic mode, demonstrating for the first time optomechanical energy conversion in a single-molecule device.

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Single-molecule optomechanical cycle

Abstract

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