The Pauli principle and nuclear spin isomers of ammonia molecules significantly reshape collective light-matter coupling in infrared cavities, demonstrated via numerical simulations for two molecules and an analytical model for ensembles.
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2 Pith papers cite this work. Polarity classification is still indexing.
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Cavity photons induce light-enhanced quantum self-trapping of vibrational excitons at weak coupling and accelerated transfer at stronger coupling, with critical strengths where dynamics freeze into stabilized many-vibron bound states.
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Nuclear Spin Isomers and the Pauli Principle in Polaritonic Chemistry
The Pauli principle and nuclear spin isomers of ammonia molecules significantly reshape collective light-matter coupling in infrared cavities, demonstrated via numerical simulations for two molecules and an analytical model for ensembles.
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Light-Induced Quantum Self-Trapping of Vibrational Excitons in an Optical Cavity
Cavity photons induce light-enhanced quantum self-trapping of vibrational excitons at weak coupling and accelerated transfer at stronger coupling, with critical strengths where dynamics freeze into stabilized many-vibron bound states.