posted on 2019-10-29, 19:03authored byJohannes Flick, Davis M. Welakuh, Michael Ruggenthaler, Heiko Appel, Angel Rubio
We
derive the full linear-response theory for nonrelativistic quantum
electrodynamics in the long wavelength limit and provide a practical
framework to solve the resulting equations by using quantum-electrodynamical
density-functional theory. We highlight how the coupling between quantized
light and matter changes the usual response functions and introduces
cross-correlated light-matter response functions. These cross-correlation
responses lead to measurable changes in Maxwell’s equations
due to the quantum-matter-mediated photon–photon interactions.
Key features of treating the combined matter-photon response are that
natural lifetimes of excitations become directly accessible from first-principles,
changes in the electronic structure due to strong light-matter coupling
are treated fully nonperturbatively, and self-consistent solutions
of the back-reaction of matter onto the photon vacuum and vice versa
are accounted for. By introducing a straightforward extension of the
random-phase approximation for the coupled matter-photon problem,
we calculate the ab initio spectra for a real molecular system that
is coupled to the quantized electromagnetic field. Our approach can
be solved numerically very efficiently. The presented framework leads
to a shift in paradigm by highlighting how electronically excited
states arise as a modification of the photon field and that experimentally
observed effects are always due to a complex interplay between light
and matter. At the same time the findings provide a route to analyze
as well as propose experiments at the interface between quantum chemistry,
nanoplasmonics and quantum optics.