On the mechanism of polaritonic rate suppression from quantum transition paths
| Autor: | Anderson, Michelle C., Woods, Esmae J., Fay, Thomas P., Wales, David J., Limmer, David T. |
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| Rok vydání: | 2023 |
| Předmět: | |
| Druh dokumentu: | Working Paper |
| Popis: | Polariton chemistry holds promise for facilitating mode-selective chemical reactions, but the underlying mechanism behind the rate modifications observed under vibrational strong coupling is not well understood. Using the recently developed quantum transition path theory, we have uncovered a mechanism of resonant suppression of a thermal reaction rate in a simple model polaritonic system, consisting of a reactive mode in a bath confined to a lossless microcavity with a single photon mode. This mechanism was uncovered by resolving the quantum dynamical reactive pathways and identifying their rate limiting transitions. Upon inspecting the wavefunctions associated with the rate limiting transition, we observed the formation of a polariton and identified the concomitant rate suppression as due to hybridization between the reactive mode and the cavity mode, which inhibits bath-mediated tunneling during the reaction. The transition probabilities that define the quantum master equation can be directly translated into a visualisation of the corresponding polariton energy landscape. This landscape exhibits a double funnel structure, with a large barrier between the initial and final states. This mechanism of resonant rate suppression is found to be robust to model parameters and computational details, and thus expected to be general. Comment: 13 pages, 6 figures, comments welcome; small clarifications added, typos and small equation error corrected, and references updated |
| Databáze: | arXiv |
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