Communication: Tailoring the optical gap in light-harvesting molecules

A. Karolewski; T. Stein; R. Baer; S. Kümmel

doi:10.1063/1.3581788

Communication: Tailoring the optical gap in light-harvesting molecules

A. Karolewski, T. Stein, R. Baer, S. Kümmel

Institute of Chemistry

The Hebrew University of Jerusalem

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

Abstract

Systematically varying the optical gap that is associated with charge-transfer excitations is an important step in the design of light-harvesting molecules. So far the guidance that time-dependent density functional theory could give in this process was limited by the traditional functionals' inability to describe charge-transfer excitations. We show that a nonempirical range-separated hybrid approach allows to reliably predict charge-transfer excitations for molecules of practically relevant complexity. Calculated absorption energies agree with measured ones. We predict from theory that by varying the number of thiophenes in donor-acceptor-donor molecules, the energy of the lowest optical absorption can be tuned to the lower end of the visible spectrum. Saturation sets in at about five thiophene rings.

Original language	English
Article number	151101
Journal	Journal of Chemical Physics
Volume	134
Issue number	15
DOIs	https://doi.org/10.1063/1.3581788
State	Published - 21 Apr 2011

All Science Journal Classification (ASJC) codes

General Physics and Astronomy
Physical and Theoretical Chemistry

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10.1063/1.3581788

Cite this

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abstract = "Systematically varying the optical gap that is associated with charge-transfer excitations is an important step in the design of light-harvesting molecules. So far the guidance that time-dependent density functional theory could give in this process was limited by the traditional functionals' inability to describe charge-transfer excitations. We show that a nonempirical range-separated hybrid approach allows to reliably predict charge-transfer excitations for molecules of practically relevant complexity. Calculated absorption energies agree with measured ones. We predict from theory that by varying the number of thiophenes in donor-acceptor-donor molecules, the energy of the lowest optical absorption can be tuned to the lower end of the visible spectrum. Saturation sets in at about five thiophene rings.",

author = "A. Karolewski and T. Stein and R. Baer and S. K{\"u}mmel",

note = "Funding Information: We acknowledge discussions with A. Neubig, M. Thelakkat, and T. K{\"o}rzd{\"o}rfer, and finanical support by Deutsche Forschungsgemeinschaft(DFG) GRK1640 and the GIF.",

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AU - Stein, T.

AU - Baer, R.

AU - Kümmel, S.

N1 - Funding Information: We acknowledge discussions with A. Neubig, M. Thelakkat, and T. Körzdörfer, and finanical support by Deutsche Forschungsgemeinschaft(DFG) GRK1640 and the GIF.

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N2 - Systematically varying the optical gap that is associated with charge-transfer excitations is an important step in the design of light-harvesting molecules. So far the guidance that time-dependent density functional theory could give in this process was limited by the traditional functionals' inability to describe charge-transfer excitations. We show that a nonempirical range-separated hybrid approach allows to reliably predict charge-transfer excitations for molecules of practically relevant complexity. Calculated absorption energies agree with measured ones. We predict from theory that by varying the number of thiophenes in donor-acceptor-donor molecules, the energy of the lowest optical absorption can be tuned to the lower end of the visible spectrum. Saturation sets in at about five thiophene rings.

AB - Systematically varying the optical gap that is associated with charge-transfer excitations is an important step in the design of light-harvesting molecules. So far the guidance that time-dependent density functional theory could give in this process was limited by the traditional functionals' inability to describe charge-transfer excitations. We show that a nonempirical range-separated hybrid approach allows to reliably predict charge-transfer excitations for molecules of practically relevant complexity. Calculated absorption energies agree with measured ones. We predict from theory that by varying the number of thiophenes in donor-acceptor-donor molecules, the energy of the lowest optical absorption can be tuned to the lower end of the visible spectrum. Saturation sets in at about five thiophene rings.

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Communication: Tailoring the optical gap in light-harvesting molecules

Abstract

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