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.
and Nitzan, Abraham and Subotnik, Joseph E
3 Pith papers cite this work. Polarity classification is still indexing.
3
Pith papers citing it
years
2026 3verdicts
UNVERDICTED 3representative citing papers
Cavity-induced shifts in thermal chemical activity are largest for low-density molecular ensembles, grow with Rabi splitting, and are strongest at low temperature when polariton dispersion and mode counting are included.
Compares Lindblad, stochastic Schrödinger, and non-Hermitian methods for dissipative Na2-cavity dynamics and shows rotational nonadiabatic effects.
citing papers explorer
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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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Thermal chemical reactivity in Frenkel exciton-polariton cavities
Cavity-induced shifts in thermal chemical activity are largest for low-density molecular ensembles, grow with Rabi splitting, and are strongest at low temperature when polariton dispersion and mode counting are included.
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Light-induced nonadiabatic dissipative quantum dynamics of the Na2 molecule
Compares Lindblad, stochastic Schrödinger, and non-Hermitian methods for dissipative Na2-cavity dynamics and shows rotational nonadiabatic effects.