Controlling cavity-induced non-adiabatic properties in molecular systems
ORAL
Abstract
Molecular cavity quantum electrodynamics aims at studying andunderstanding the interaction of confined electromagnetic field modes withmolecules. The coupling between photons andmolecules gives rise to mixed light-matter states which are called polaritons carrying both photonic andmolecular features.
Experimental and theoretical works have demonstrated that polaritonic states can dramatically alter physical and chemical properties of molecular systems.
In this presentation results are shown how the strong non-adiabatic effect created by quantum light can modify and control the different topological,
spectroscopic and dynamical properties of molecular systems.
Experimental and theoretical works have demonstrated that polaritonic states can dramatically alter physical and chemical properties of molecular systems.
In this presentation results are shown how the strong non-adiabatic effect created by quantum light can modify and control the different topological,
spectroscopic and dynamical properties of molecular systems.
*The authors are indebted to NKFIH for funding (Grant No. K146096). Deutsche Forschungsgemeinschaft (DFG Grant No. CE 10/56-1) is also acknowledged.
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Publication: 1. C. Fábri, G. J. Halász and Á. Vibók: JPCL, 13, 1172 (2022);
2. C. Fábri, G. J. Halász and Á. Vibók: Impact of Cavity on Molecular Ionization Spectra, submitted to JPCL;
3. C. Fábri, A. Csehi, G. J. Halász, L. S. Cederbaum and Á. Vibók: Classical and quantum light-induced non-adiabaticity in molecular systems, submitted to AVS Quantum Science.
Presenters
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Agnes Vibok
- University of Debrecen