Litcius/Paper detail

Photoisomerization transition state manipulation by entangled two-photon absorption

Bing Gu, Daniel Keefer, Flavia Aleotti, Artur Nenov, Marco Garavelli, Shaul Mukamel

2021Proceedings of the National Academy of Sciences19 citationsDOIOpen Access PDF

Abstract

isomerization following entangled two-photon excitation is simulated using quantum nuclear wave packet dynamics. Photon entanglement modulates the nuclear wave packets by coherently controlling the transition pathways. The photochemical transition state during passage of the reactive conical intersection in azobenzene photoisomerization is strongly affected with a noticeable alteration of the product yield. Quantum entanglement thus provides a novel control knob for photochemical reactions. The distribution of the vibronic coherences during the conical intersection passage strongly depends on the shape of the initial wave packet created upon quantum light excitation. X-ray signals that can experimentally monitor this coherence are simulated.

Topics & Concepts

PhotoisomerizationState (computer science)Absorption (acoustics)PhotonTransition (genetics)Two-photon excitation microscopyPhotochemistryChemistryPhysicsOpticsIsomerizationComputer scienceBiochemistryCatalysisGeneAlgorithmFluorescenceNonlinear Optical Materials StudiesPhotochromic and Fluorescence ChemistryAdvanced Fluorescence Microscopy Techniques