Visualizing Conical Intersection Passages via Vibronic Coherence Maps Generated by Stimulated Ultrafast X--Ray Raman Signals

TL;DR

This study demonstrates how ultrafast X-ray Raman signals can visualize and measure vibronic coherence at conical intersections in molecules, providing new insights into photophysical processes.

Contribution

It introduces a method to directly observe and map conical intersection pathways using stimulated ultrafast X-ray Raman spectroscopy and coherence analysis.

Findings

Vibronic coherence at conical intersections persists for hundreds of femtoseconds.

Time-dependent energy landscapes of vibrational and electronic states are extractable from signals.

The nuclear wavepacket pathway around the conical intersection can be visualized.

Abstract

The rates and outcomes of virtually all photophysical and photochemical processes are determined by Conical Intersections. These are regions of degeneracy between electronic states on the nuclear landscape of molecules where electrons and nuclei evolve on comparable timescales and become strongly coupled, enabling radiationless relaxation channels upon optical excitation. Due to their ultrafast nature and vast complexity, monitoring Conical Intersections experimentally is an open challenge. We present a simulation study on the ultrafast photorelaxation of uracil, which demonstrates a new window into Conical Intersections obtained by recording the transient wavepacket coherence during this passage with an x-ray free electron laser pulse. We report two major findings. First, we find that the vibronic coherence at the conical intersection lives for several hundred femtoseconds and can be measured during this entire time. Second, the time-dependent energy splitting landscape of the participating vibrational and electronic states is directly extracted from Wigner spectrograms of the signal. These offer a novel physical picture of the quantum Conical Intersection pathways through visualizing their transient vibronic coherence distributions. The path of a nuclear wavepacket around the Conical Intersection is directly mapped by the proposed experiment.