Bulletin of the American Physical Society
54th Annual Meeting of the APS Division of Atomic, Molecular and Optical Physics
Volume 68, Number 7
Monday–Friday, June 5–9, 2023; Spokane, Washington
Session F02: Virtual Poster Session (4:00pm-6:00pm, PT)
4:00 PM,
Tuesday, June 6, 2023
Room: Virtual Platform
Chair: Jianming Wen, Kennesaw State University
Abstract: F02.00013 : Ballistic or statistic - The few-femtosecond dissociative dynamics of a bifurcating Jahn-Teller system*
Presenter:
Danylo T Matselyukh
(ETH Zurich)
Authors:
Danylo T Matselyukh
(ETH Zurich)
Vit Svoboda
(ETH Zurich)
Hans Jakob Wörner
(ETH Zurich)
Photoionised tetrahedral silane (SiH4) is an example of such a highly symmetric and unstable system, known to fragment into SiH2+ and SiH3+, . Thanks to the unprecedented time-resolution offered by Soft X-Ray (SXR) attosecond transient absorption spectroscopy (ATAS) we are able to capture the short-lived transient species involved in the JT fragmentation of SiH4+ and for the first time untangle the competing dynamics that lead to the distinct fragments.
Our ATAS results show that bifurcation in the dynamics occurs immediately after ionisation. The SiH3+ fragment is created as a result of the T2×t2 JT effect within 30 fs of ionisation through a strong activation of the ν4 asymmetric bending mode. This dissociation is found to be ballistic; it proceeds without a barrier and creates vibrational coherence in the fragment which we experimentally observe. This wavepacket in the umbrella mode is found to dephase within 100 fs due to the large amplitude of the vibration.
The dynamics of the SiH2+ dissociation are found to be the strikingly different. For this pathway, the initial motion of the system is driven by the T2×e JT effect, bringing it into a local D2d minimum along the ν2 scissoring mode. We are able to experimentally identify the spectroscopic signature of this transient species through its vibrational quantum beats, and find that it is only able to dissociate further into the SiH2+ fragment through the anharmonic transfer of vibrational energy from the e mode into the t2 modes. This process occurs statistically, resulting in a loss of vibrational coherence and the negative exponential rise of the SiH2+ fragment’s spectral signature with a 155 fs timescale.
*We acknowledge funding from the ERC Consolidator Grant (project no. 772797-ATTOLIQ), from the Swiss National Science Foundation through projects 200021_172946 and the NCCR-MUST.
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