Modulating unimolecular charge transfer by exciting bridge vibrations.

Abstract

Ultrafast UV-vibrational spectroscopy was used to investigate how vibrational excitation of the bridge changes photoinduced electron transfer between donor (dimethylaniline) and acceptor (anthracene) moieties bridged by a guanosine-cytidine base pair (GC). The charge-separated (CS) state yield is found to be lowered by high-frequency bridge mode excitation. The effect is linked to a dynamic modulation of the donor-acceptor coupling interaction by weakening of H-bonding and/or by disruption of the bridging base-pair planarity.

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Citation

Published Version (Please cite this version)

10.1021/ja907041t

Publication Info

Lin, Zhiwei, Candace M Lawrence, Dequan Xiao, Victor V Kireev, Spiros S Skourtis, Jonathan L Sessler, David N Beratan, Igor V Rubtsov, et al. (2009). Modulating unimolecular charge transfer by exciting bridge vibrations. J Am Chem Soc, 131(50). pp. 18060–18062. 10.1021/ja907041t Retrieved from https://hdl.handle.net/10161/4047.

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Scholars@Duke

Beratan

David N. Beratan

R.J. Reynolds Distinguished Professor of Chemistry

Dr. Beratan is developing theoretical approaches to understand the function of complex molecular and macromolecular systems, including: the molecular underpinnings of energy harvesting and charge transport in biology; the mechanism of solar energy capture and conversion in man-made structures; the nature of charge conductivity in naturally occurring nucleic acids and in synthetic constructs, including the photochemical repair of damaged DNA in extremophiles; CH bond activation by copper oxygenase enzymes; the flow of charge in bacterial appendages on the micrometer length scale; the theoretical foundations for inverse molecular design - the property driven discovery of chemical structures with optimal properties; the exploitation of molecular diversity in the mapping of molecular and materials "space"; the use of infra-red excitation to manipulate electron transport through molecules; the optical signatures of molecular chirality and the influence of chirality on charge transport. Prof. Beratan is affiliated with the Departments of Chemistry, Biochemistry, Physics, as well as Duke's programs in Computational Biology and Bioinformatics, Structural Biology and Biophysics, Nanosciences, and Phononics.  


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