Frequency-dependent response functions are implemented for QED-HF theory, benchmarked against real-time simulations, and shown to exhibit cavity-induced changes at certain frequencies with null effects at others regardless of coupling strength.
Title resolution pending
4 Pith papers cite this work. Polarity classification is still indexing.
years
2026 4verdicts
UNVERDICTED 4representative citing papers
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.
Cavity QED modifies DBOC, producing few cm^{-1} shifts in molecular dissociation energies and larger effects in some atoms that reach experimental resolution.
Compares Lindblad, stochastic Schrödinger, and non-Hermitian methods for dissipative Na2-cavity dynamics and shows rotational nonadiabatic effects.
citing papers explorer
-
Dynamic Response Functions for Cavity Quantum Electrodynamics Hartree-Fock Theory
Frequency-dependent response functions are implemented for QED-HF theory, benchmarked against real-time simulations, and shown to exhibit cavity-induced changes at certain frequencies with null effects at others regardless of coupling strength.
-
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.
-
Non-adiabatic Effects Induced by Strong Light-Matter Coupling in Cavity QED
Cavity QED modifies DBOC, producing few cm^{-1} shifts in molecular dissociation energies and larger effects in some atoms that reach experimental resolution.
-
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.