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Bléger D, Dokić J, Peters MV, et al. Electronic decoupling approach to quantitative photoswitching in linear multiazobenzene architectures. J Phys Chem B. 2011;115(33):9930-40doi: 10.1021/jp2044114.
Bléger, D., Dokić, J., Peters, M. V., Grubert, L., Saalfrank, P., & Hecht, S. (2011). Electronic decoupling approach to quantitative photoswitching in linear multiazobenzene architectures. The journal of physical chemistry. B, 115(33), 9930-40. https://doi.org/10.1021/jp2044114
Bléger, David, et al. "Electronic decoupling approach to quantitative photoswitching in linear multiazobenzene architectures." The journal of physical chemistry. B vol. 115,33 (2011): 9930-40. doi: https://doi.org/10.1021/jp2044114
Bléger D, Dokić J, Peters MV, Grubert L, Saalfrank P, Hecht S. Electronic decoupling approach to quantitative photoswitching in linear multiazobenzene architectures. J Phys Chem B. 2011 Aug 25;115(33):9930-40. doi: 10.1021/jp2044114. Epub 2011 Aug 02. PMID: 21749103.
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J Phys Chem B. 2011 Aug 25;115(33):9930-40. doi: 10.1021/jp2044114. Epub 2011 Aug 02.

Electronic decoupling approach to quantitative photoswitching in linear multiazobenzene architectures.

The journal of physical chemistry. B

David Bléger, Jadranka Dokić, Maike V Peters, Lutz Grubert, Peter Saalfrank, Stefan Hecht

Affiliations

  1. Department of Chemistry, Humboldt-Universität zu Berlin, Brook-Taylor-Str. 2, 12489 Berlin, Germany.

PMID: 21749103 DOI: 10.1021/jp2044114

Abstract

A strategy to optimize the photoswitching efficiency of rigid, linear multiazobenzene constructs is presented. It consists of introducing large dihedral angles between azobenzene moieties linked via aryl-aryl connections in their para positions. Four bisazobenzenes exhibiting different dihedral angles as well as three single azobenzene reference compounds have been synthesized, and their switching behavior has been studied as well as experimentally and theoretically analyzed. As the dihedral angle between the two azobenzene units increases and consequently the electronic conjugation decreases, the photochromic characteristics improve, finally leading to individual azobenzene switches operating independently in the case of the perpendicular ortho,ortho,ortho',ortho'-tetramethyl biphenyl linker. The electronic decoupling leads to efficient separation of the absorption spectra of the involved switching states and hence by choosing the appropriate irradiation wavelength, an almost quantitative E → Z photoisomerization up to 97% overall Z-content can be achieved. In addition, thermal Z → E isomerization processes become independent of each other with increasing decoupling. The electronic decoupling could furthermore be proven by electrochemistry. The experimental data are supported by theory, and calculations additionally provide mechanistic insight into the preferred pathway for the thermal Z,Z → Z,E → E,E isomerization via inversion on the inner N-atoms. Our decoupling approach outlined herein provides the basis for constructing rigid rod architectures composed of multiple azobenzene photochromes, which display practically quantitative photoswitching properties, a necessary prerequisite to achieve highly efficient transduction of light energy directly into motion.

© 2011 American Chemical Society

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