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Main Authors: Bustamante, Carlos M., Bonafé, Franco P., Richardson, Richard, Ruggenthaler, Michael, Ying, Wenxiang, Nitzan, Abraham, Sukharev, Maxim, Rubio, Angel
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.16299
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author Bustamante, Carlos M.
Bonafé, Franco P.
Richardson, Richard
Ruggenthaler, Michael
Ying, Wenxiang
Nitzan, Abraham
Sukharev, Maxim
Rubio, Angel
author_facet Bustamante, Carlos M.
Bonafé, Franco P.
Richardson, Richard
Ruggenthaler, Michael
Ying, Wenxiang
Nitzan, Abraham
Sukharev, Maxim
Rubio, Angel
contents Molecular polaritons arise from electronic or vibrational strong coupling (ESC and VSC) with confined electromagnetic fields. While these have been widely studied, the influence of electron-nuclear dynamics in driven cavities remains largely unknown. Here, we report a previously unrecognized mechanism of vibrational activation that emerges under collective ESC in driven optical cavities. Using simulations that self-consistently combine Maxwell's equations with quantum molecular dynamics, we show that collective electronic Rabi oscillations coherently drive nuclear motion. This effect is captured using both vibrational wave-packet dynamics in a minimal two-level model and atomistic simulations based on time-dependent density-functional tight-binding theory. Vibrational activation depends non-monotonically on the Rabi frequency and is maximized when the collective polaritonic splitting resonates with a molecular vibrational mode. The mechanism exhibits features consistent with a stimulated Raman-like relaxation mechanism. Our predictions are robust under realistic cavity conditions and provide the conditions in which they could be verified experimentally.
format Preprint
id arxiv_https___arxiv_org_abs_2601_16299
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Collective Rabi-driven vibrational activation in molecular polaritons
Bustamante, Carlos M.
Bonafé, Franco P.
Richardson, Richard
Ruggenthaler, Michael
Ying, Wenxiang
Nitzan, Abraham
Sukharev, Maxim
Rubio, Angel
Computational Physics
Molecular polaritons arise from electronic or vibrational strong coupling (ESC and VSC) with confined electromagnetic fields. While these have been widely studied, the influence of electron-nuclear dynamics in driven cavities remains largely unknown. Here, we report a previously unrecognized mechanism of vibrational activation that emerges under collective ESC in driven optical cavities. Using simulations that self-consistently combine Maxwell's equations with quantum molecular dynamics, we show that collective electronic Rabi oscillations coherently drive nuclear motion. This effect is captured using both vibrational wave-packet dynamics in a minimal two-level model and atomistic simulations based on time-dependent density-functional tight-binding theory. Vibrational activation depends non-monotonically on the Rabi frequency and is maximized when the collective polaritonic splitting resonates with a molecular vibrational mode. The mechanism exhibits features consistent with a stimulated Raman-like relaxation mechanism. Our predictions are robust under realistic cavity conditions and provide the conditions in which they could be verified experimentally.
title Collective Rabi-driven vibrational activation in molecular polaritons
topic Computational Physics
url https://arxiv.org/abs/2601.16299