Coupling of photoactive transition metal complexes to a functional polymer matrix** |
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| Authors: | Miftahussurur Hamidi Putra Sebastian Seidenath Dr Stephan Kupfer Prof Dr Stefanie Gräfe Prof Dr Axel Groß |
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| Institution: | 1. Institute of Theoretical Chemistry, Ulm University, 89069 Ulm, Germany;2. Institute for Physical Chemistry (IPC) and Abbe Center of Photonics, Friedrich Schiller University Jena, Helmholtzweg 4, 07743 Jena |
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| Abstract: | Conductive polymers represent a promising alternative to semiconducting oxide electrodes typically used in dye-sensitized cathodes as they more easily allow a tuning of the physicochemical properties. This can then also be very beneficial for using them in light-driven catalysis. In this computational study, we address the coupling of Ru-based photosensitizers to a polymer matrix by combining two different first-principles electronic structure approaches. We use a periodic density functional theory code to properly account for the delocalized nature of the electronic states in the polymer. These ground state investigations are complemented by time-dependent density functional theory simulations to assess the Franck-Condon photophysics of the present photoactive hybrid material based on a molecular model system. Our results are consistent with recent experimental observations and allow to elucidate the light-driven redox chemical processes – eventually leading to charge separation – in the present functional hybrid systems with potential application as photocathode materials. |
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| Keywords: | organic solar cells photoactive complexes polymer matrix quantum chemistry electronic coupling |
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