2020
DOI: 10.1021/acs.jpclett.0c02236
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Photoprotecting Uracil by Coupling with Lossy Nanocavities

Abstract: We analyze how the photorelaxation dynamics of a molecule can be controlled by modifying its electromagnetic environment using a nanocavity mode. In particular, we consider the photorelaxation of the RNA nucleobase uracil, which is the natural mechanism to prevent photodamage. In our theoretical work, we identify the operative conditions in which strong coupling with the cavity mode can open an efficient photoprotective channel, resulting in a relaxation dynamics twice as fast as the natural one. We rely on a … Show more

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Cited by 79 publications
(101 citation statements)
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“…This reduction is increased when the cavity resonance is shifted to lower energies, highlighting the importance of the photon decay of the cavity mode for excited state reactions in the strong coupling regime. [ 11,25 ] Furthermore, we show that the back reaction is not affected by the strong coupling regime since it occurs on the ground state potential energy surface. The system therefore has a red‐shifted onset of absorption and at the same time a retained back reaction.…”
Section: Discussionmentioning
confidence: 82%
“…This reduction is increased when the cavity resonance is shifted to lower energies, highlighting the importance of the photon decay of the cavity mode for excited state reactions in the strong coupling regime. [ 11,25 ] Furthermore, we show that the back reaction is not affected by the strong coupling regime since it occurs on the ground state potential energy surface. The system therefore has a red‐shifted onset of absorption and at the same time a retained back reaction.…”
Section: Discussionmentioning
confidence: 82%
“…As a general remark, to minimize computational cost, the Lindblad master equation can be reduced to a non-Hermitian Schrodinger equation employing an absorbing potential, given the following three conditions: The Hamiltonian does not couple any state in the subspace to other states that are not in the subspace, the initial state projected onto that subspace is a pure state, and the subspace is not the recipient of decaying states. This motivates the method in previous studies, 19 21 but in this study, these conditions only apply to the doubly excited subspace (see Fig. 2 for definitions of subspaces).…”
Section: System and Modelmentioning
confidence: 84%
“…It is worth noting that the stability optimum is at the border of the strong coupling regime, which has also been found in other studies. 21 This suggests that it may be an interplay of strong coupling and cavity cooling, which is required to explain polaritonic chemistry experiments.…”
Section: Discussionmentioning
confidence: 99%
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