Abstract
A detailed understanding of strong matter–photon interactions requires first-principle methods that can solve the fundamental Pauli–Fierz Hamiltonian of nonrelativistic quantum electrodynamics efficiently. A possible way to extend well-established electronic-structure methods to this situation is to embed the Pauli–Fierz Hamiltonian in a higher-dimensional light–matter hybrid auxiliary configuration space. In this work we show the importance of the resulting hybrid Fermi–Bose statistics of the polaritons, which are the new fundamental particles of the “photon-dressed” Pauli–Fierz Hamiltonian for systems in cavities. We show that violations of these statistics can lead to unphysical results. We present an efficient way to ensure the correct statistics by enforcing representability conditions on the dressed one-body reduced density matrix. We further present a general prescription how to extend a given first-principles approach to polaritons and as an example introduce polaritonic Hartree–Fock theory. While being a single-reference method in polariton space, polaritonic Hartree–Fock is a multireference method in the electronic space, i.e., it describes electronic correlations. We also discuss possible applications to polaritonic QEDFT. We apply this theory to a lattice model and find that, the more delocalized the bound-state wave function of the particles is, the stronger it reacts to photons. The main reason is that within a small energy range, many states with different electronic configurations are available as opposed to a strongly bound (and hence energetically separated) ground-state wave function. This indicates that under certain conditions coupling to the quantum vacuum of a cavity can indeed modify ground state properties.
Highlights
A detailed understanding of strong matter−photon interactions requires first-principle methods that can solve the fundamental Pauli−Fierz Hamiltonian of nonrelativistic quantum electrodynamics efficiently
We have highlighted the influence of the hybrid Fermi−Bose statistics of the polariton wave function in the dressed construction
We have provided a simple and general prescription on how to turn a given electronic-structure method into a polaritonic-structure method by introducing conditions in terms of the 1RDM to ensure the right hybrid statistics
Summary
This new structure is the basis of the class of first-principles approaches that we propose in this article (see section 3) To conclude this brief summary of the dressed construction, we want to mention that while the matter observables stay unchanged, the photon observables like the photon energy Ĥ ph or the displacement coordinate of the photon modes pα have different representations in the auxiliary configuration space. We constrain this space by enforcing the N-representability conditions of eq 23 for the 1RDM of the electronic subsystem Since this guarantees that only (ensembles of) fermionc wave functions are allowed, the minimal energy solution (corresponds to an ensemble that) has fermionc symmetry with respect to rσ. We will based on the polariton ansatz provide a detailed prescription to generalize a given electronic-structure theory to treat ground states of coupled electron−photon systems from first principles
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
