The importance of a backbone: The mechanism of formation of Dewar lesions has been investigated by using femtosecond IR spectroscopy and ab initio calculations of the exited state. The 4π electrocyclization is rather slow, occurs with an unusual high quantum yield, and--surprisingly--is controlled by the phosphate backbone.
A combined experimental and theoretical investigation of photoinduced Z/E isomerizations is presented. Unsubstituted Hemithioindigo is selected as a representative minimal model to unravel the reaction mechanism in the presence of heteroatoms on an atomic level. Time-resolved spectroscopy reveals multiexponential reaction dynamics on the few picoseconds time scale, which are interpreted by quantum chemical calculations at the CASSCF/CASPT2 level of theory. Detailed insight into the processes governing the ultrafast decay from the first excited state, mediated by a number of conical intersections, is provided. Charge separation and charge balance recovery on the reaction pathway play the leading role and are controlled by the electron-donating or -withdrawing character of the heteroatoms. The electronic and geometric structures of the individual minimum energy conical intersections governing the reaction are rationalized, and an extended energetically low lying conical intersection seam is extracted. Comparison to the experimental results permits linking the observed time constants to molecular intermediates and pathways. An explanation is provided for the pronounced differences of Z → E and the E → Z photoreactions upon excitation to the first excited singlet state.
Two hemithioindigo-hemistilbene (HTI) derivatives, designed to operate as structural switches in peptides, as well as two HTI peptides are characterized by ultrafast spectroscopy in the visible and the infrared. The two HTI switches follow the reaction scheme published for other HTI compounds with a picosecond excited state reaction (τ(1) ≈ 6 ps) and isomerization from Z to E with τ(2) = 13 and 51 ps. As compared to the isolated chromophores, the isomerization reaction is slowed down in the chromopeptides to τ(2) = 24 and 69 ps. For the smaller peptide containing 6 amino acids, the structural changes of the peptide moiety observed via the IR spectrum in the amide I band follow the isomerization of the molecular switch closely. In the larger cyclic chromopeptide, containing 20 amino acids and mimicking a β-hairpin structure in the Z-form of the chromophore, the peptide moiety also changes its structure during isomerization of the chromophore. However, the IR spectrum at the end of the observation period of 3 ns deviates significantly from the stationary difference spectrum. These signatures indicate that strong additional structural changes, e.g., breaking of interchain hydrogen bonds, also occur on longer time scales.
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