Exact functionals for correlated electron–photon systems

Dimitrov, Tanja; Ruggenthaler, Michael; Rubio, Ángel

doi:10.1088/1367-2630/aa8f09

Cited by 25 publications

(33 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This allows a consistent and predictive description of the behavior of strongly coupled ensembles including a macroscopic number of molecules. First-principles approaches are explored in ref. 50, 51 and 60 .…”

Section: Introductionmentioning

confidence: 99%

Polariton chemistry: controlling molecular dynamics with optical cavities

et al. 2018

View full text Add to dashboard Cite

show abstract

Section: Introductionmentioning

confidence: 99%

Polariton chemistry: controlling molecular dynamics with optical cavities

et al. 2018

View full text Add to dashboard Cite

show abstract

“…Here R(t) = ψ(t)|Rψ(t) and ψ(t) a purely electronic wave-function. For a static problem we therefore find, in accordance to the fact that p α actually corresponds to the displacement field, that we are left with the polarization term only, i.e., in equilibrium D = P[ψ] = ψ|P ψ and the electric field is zero as it should for an eigen-state [40,49]. If we further choose a symmetric binding potential at the origin, the eigen-states have zero dipole-moment and we reduce to the usual HamiltonianĤ e plus the dipole-self energy.…”

Section: B the Semi-classical Limitmentioning

confidence: 57%

“…Finally, by usingÂ tot (t) = (Â + A(t)) and combining both above derivations we can include also time-dependent fields. Note, however, that we can always exchange an external field by an appropriately chosen external time-dependent current [49]. To conclude, the semiclassical limit performed after the length-gauge transformations supports eigen-states due to the presence of the dipole self-energy term in contrast to the standard semi-classical limit.…”

Section: B the Semi-classical Limitmentioning

confidence: 65%

Light–matter interaction in the long-wavelength limit: no ground-state without dipole self-energy

Rokaj¹,

Welakuh²,

Ruggenthaler³

et al. 2018

J. Phys. B: At. Mol. Opt. Phys.

Self Cite

198

293

View full text Add to dashboard Cite

Most theoretical studies for correlated light-matter systems are performed within the longwavelength limit, i.e., the electromagnetic field is assumed to be spatially uniform. In this limit the so-called length-gauge transformation for a fully quantized light-matter system gives rise to a dipole self-energy term in the Hamiltonian, i.e., a harmonic potential of the total dipole matter moment. In practice this term is often discarded as it is assumed to be subsumed in the kinetic energy term. In this work we show the necessity of the dipole self-energy term. First and foremost, without it the light-matter system in the long-wavelength limit does not have a ground-state, i.e., the combined light-matter system is unstable. Further, the mixing of matter and photon degrees of freedom due to the length-gauge transformation, which also changes the representation of the translation operator for matter, gives rise to the Maxwell equations in matter and the omittance of the dipole self-energy leads to a violation of these equations. Specifically we show that without the dipole self-energy the so-called "depolarization shift" is not properly described. Finally we show that this term also arises if we perform the semi-classical limit after the length-gauge transformation. In contrast to the standard approach where the semi-classical limit is performed before the length-gauge transformation, the resulting Hamiltonian is bounded from below and thus supports ground states. This is very important for practical calculations and for density-functional variational implementations of the non-relativistic QED formalism. For example, the existence of a combined light-matter ground state allows to calculate the Stark shift non-perturbatively. *

show abstract

“…This approach to coupled electron-photon dynamics is complementary to the recently developed TDDFT approach to cavity QED. Indeed, the e-ph correlation potential which was the heart of our investigation in this work is closely related to the correlation potential of the cavity QED (TD)DFT, therefore, the features of the e-ph correlation potential we discussed in this work together with the analytical approximation of the potential presented here are particularly relevant for developing the cavity QED (TD)DFT exchange-correlation functionals [25,26]. Another interesting avenue to explore is the connection between the approach proposed here and the Born-Huang expansion approach for the cavity QED that has been proposed very recently [63].…”

Section: Discussionmentioning

confidence: 93%

Shedding light on correlated electron–photon states using the exact factorization

2018

View full text Add to dashboard Cite

The Exact Factorization framework is extended and utilized to introduce the electronic-states of correlated electron-photon systems. The formal definitions of an exact scalar potential and an exact vector potential that account for the electron-photon correlation are given. Inclusion of these potentials to the Hamiltonian of the uncoupled electronic system leads to a purely electronic Schrödinger equation that uniquely determines the electronic states of the complete electron-photon system. For a one-dimensional asymmetric double-well potential coupled to a single photon mode with resonance frequency, we investigate the features of the exact scalar potential. In particular, we discuss the significance of the step-and-peak structure of the exact scalar potential in describing the phenomena of photon-assisted delocalization and polaritonic squeezing of the electronic excited-states. In addition, we develop an analytical approximation for the scalar potential and demonstrate how the step-and-peak features of the exact scalar potential are captured by the proposed analytical expression.PACS. PACS-key discribing text of that key -PACS-key discribing text of that key

show abstract

Exact functionals for correlated electron–photon systems

Cited by 25 publications

References 43 publications

Polariton chemistry: controlling molecular dynamics with optical cavities

Polariton chemistry: controlling molecular dynamics with optical cavities

Light–matter interaction in the long-wavelength limit: no ground-state without dipole self-energy

Shedding light on correlated electron–photon states using the exact factorization

Contact Info

Product

Resources

About