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Quantum-electrodynamical time-dependent density functional theory within Gaussian atomic basis

Junjie Yang, Qi Ou, Zheng Pei, Hua Wang, Binbin Weng, Zhigang Shuai, Kieran Mullen, Yihan Shao

2021The Journal of Chemical Physics72 citationsDOIOpen Access PDF

Abstract

Inspired by the formulation of quantum-electrodynamical time-dependent density functional theory (QED-TDDFT) by Rubio and co-workers [Flick et al., ACS Photonics 6, 2757-2778 (2019)], we propose an implementation that uses dimensionless amplitudes for describing the photonic contributions to QED-TDDFT electron-photon eigenstates. This leads to a Hermitian QED-TDDFT coupling matrix that is expected to facilitate the future development of analytic derivatives. Through a Gaussian atomic basis implementation of the QED-TDDFT method, we examined the effect of dipole self-energy, rotating-wave approximation, and the Tamm-Dancoff approximation on the QED-TDDFT eigenstates of model compounds (ethene, formaldehyde, and benzaldehyde) in an optical cavity. We highlight, in the strong coupling regime, the role of higher-energy and off-resonance excited states with large transition dipole moments in the direction of the photonic field, which are automatically accounted for in our QED-TDDFT calculations and might substantially affect the energies and compositions of polaritons associated with lower-energy electronic states.

Topics & Concepts

PhysicsGaussianBasis (linear algebra)Coupling (piping)DipolePhotonicsEigenvalues and eigenvectorsQuantum mechanicsDimensionless quantityHermitian matrixDensity functional theoryExcited statePolaritonStatistical physicsMoment (physics)AmplitudeDensity matrixMatrix (chemical analysis)Biorthogonal systemProbability amplitudeProbability density functionTransition dipole momentDiscrete dipole approximationGaussian processBasis functionStrong Light-Matter InteractionsQuantum Electrodynamics and Casimir EffectMechanical and Optical Resonators