%0 Journal Article %1 C6CP03053J %A Lambert, C. %A Moos, M. %A Schmiedel, A. %A Holzapfel, M. %A Schafer, J. %A Kess, M. %A Engel, V. %D 2016 %I The Royal Society of Chemistry %J Phys. Chem. Chem. Phys. %K ak-engel %N 28 %P 19405-19411 %R 10.1039/C6CP03053J %T How fast is optically induced electron transfer in organic mixed valence systems? %U http://dx.doi.org/10.1039/C6CP03053J %V 18 %X The rate of thermally induced electron transfer in organic mixed valence compounds has thoroughly been investigated by e.g. temperature dependent ESR spectroscopy. However, almost nothing is known about the dynamics of optically induced electron transfer processes in such systems. Therefore, we investigated these processes in mixed valence compounds based on triphenylamine redox centres bridged by conjugated spacers by NIR transient absorption spectroscopy with fs-time resolution. These experiments revealed an internal conversion (IC) process to be on the order of 50-200 fs which is equivalent to the back electron transfer after optical excitation into the intervalence charge transfer band. This IC is followed by ultrafast cooling to the ground state within 1 ps. Thus, in the systems investigated optically induced electron transfer is about 3-4 orders of magnitude faster than thermally induced ET.

@article{C6CP03053J, abstract = {The rate of thermally induced electron transfer in organic mixed valence compounds has thoroughly been investigated by e.g. temperature dependent ESR spectroscopy. However{,} almost nothing is known about the dynamics of optically induced electron transfer processes in such systems. Therefore{,} we investigated these processes in mixed valence compounds based on triphenylamine redox centres bridged by conjugated spacers by NIR transient absorption spectroscopy with fs-time resolution. These experiments revealed an internal conversion (IC) process to be on the order of 50-200 fs which is equivalent to the back electron transfer after optical excitation into the intervalence charge transfer band. This IC is followed by ultrafast cooling to the ground state within 1 ps. Thus{,} in the systems investigated optically induced electron transfer is about 3-4 orders of magnitude faster than thermally induced ET.}, added-at = {2017-06-20T16:33:31.000+0200}, author = {Lambert, C. and Moos, M. and Schmiedel, A. and Holzapfel, M. and Schafer, J. and Kess, M. and Engel, V.}, biburl = {https://www.bibsonomy.org/bibtex/2184f2421ef688103b13cb886a3041a95/ak-engel-uniwue}, description = {How fast is optically induced electron transfer in organic mixed valence systems? - Physical Chemistry Chemical Physics (RSC Publishing)}, doi = {10.1039/C6CP03053J}, interhash = {a53849bea12e8ae664b51b0f9fb581b1}, intrahash = {184f2421ef688103b13cb886a3041a95}, journal = {Phys. Chem. Chem. Phys.}, keywords = {ak-engel}, number = 28, pages = {19405-19411}, publisher = {The Royal Society of Chemistry}, timestamp = {2017-06-20T16:33:31.000+0200}, title = {How fast is optically induced electron transfer in organic mixed valence systems?}, url = {http://dx.doi.org/10.1039/C6CP03053J}, volume = 18, year = 2016 }