63 research outputs found
Reduced purities as measures of decoherence in many-electron systems
A hierarchy of measures of decoherence for many-electron systems that is
based on the purity and the hierarchy of reduced electronic density matrices is
presented. These reduced purities can be used to characterize electronic
decoherence in the common case when the many-body electronic density matrix is
not known and only reduced information about the electronic subsystem is
available. Being defined from reduced electronic quantities, the interpretation
of the reduced purities is more intricate than the usual (many-body) purity.
This is because the nonidempotency of the -body reduced electronic density
matrix that is the basis of the reduced purity measures can arise due to
decoherence or due to electronic correlations. To guide the interpretation,
explicit expressions are provided for the one-body and two-body reduced
purities for a general electronic state. Using them, the information content
and structure of the one-body and two-body reduced purities is established, and
limits on the changes that decoherence can induce are elucidated. The practical
use of the reduced purities to understand decoherence dynamics in many-electron
systems is exemplified through an analysis of the electronic decoherence
dynamics in a model molecular system.Comment: 10 pages, 3 figure
Stochastic quantum molecular dynamics for finite and extended systems
We present a detailed account of the technical aspects of stochastic quantum
molecular dynamics, an approach introduced recently by the authors [H. Appel
and M. Di Ventra, Phys. Rev. B 80 212303 (2009)] to describe coupled
electron-ion dynamics in open quantum systems. As example applications of the
method we consider both finite systems with and without ionic motion, as well
as describe its applicability to extended systems in the limit of classical
ions. The latter formulation allows the study of important phenomena such as
decoherence and energy relaxation in bulk systems and surfaces in the presence
of time-dependent fields
A quantum reactive scattering perspective on electronic nonadiabaticity
Based on quantum reactive-scattering theory, we propose a method for studying
the electronic nonadiabaticity in collision processes involving electron-ion
rearrangements. We investigate the state-to-state transition probability for
electron-ion rearrangements with two comparable approaches. In the first
approach the information of the electron is only contained in the ground-state
Born-Oppenheimer potential-energy surface, which is the starting point of
common reactive-scattering calculations. In the second approach, the electron
is explicitly taken into account and included in the calculations at the same
level as the ions. Hence, the deviation in the results between the two
approaches directly reflects the electronic nonadiabaticity during the
collision process. To illustrate the method, we apply it to the well-known
proton-transfer model of Shin and Metiu (one electron and three ions),
generalized by us in order to allow for reactive scattering channels. It is
shown that our explicit electron approach is able to capture electronic
nonadiabaticity and the renormalization of the reaction barrier near the
classical turning points of the potential in nuclear configuration space. In
contrast, system properties near the equilibrium geometry of the asymptotic
scattering channels are hardly affected by electronic nonadiabatic effects. We
also present an analytical expression for the transition amplitude of the
asymmetric proton-transfer model based on the direct evaluation of integrals
over the involved Airy functions.Comment: 14 page
Atoms and Molecules in Cavities: From Weak to Strong Coupling in QED Chemistry
In this work, we provide an overview of how well-established concepts in the
fields of quantum chemistry and material sciences have to be adapted when the
quantum nature of light becomes important in correlated matter-photon problems.
Therefore, we analyze model systems in optical cavities, where the
matter-photon interaction is considered from the weak- to the strong coupling
limit and for individual photon modes as well as for the multi-mode case. We
identify fundamental changes in Born-Oppenheimer surfaces, spectroscopic
quantities, conical intersections and efficiency for quantum control. We
conclude by applying our novel recently developed quantum-electrodynamical
density-functional theory to single-photon emission and show how a
straightforward approximation accurately describes the correlated
electron-photon dynamics. This paves the road to describe matter-photon
interactions from first-principles and addresses the emergence of new states of
matter in chemistry and material science
Kohn-Sham Approach to Quantum Electrodynamical Density Functional Theory: Exact Time-Dependent Effective Potentials in Real Space
The density-functional approach to quantum electrodynamics is extending
traditional density-functional theory and opens the possibility to describe
electron-photon interactions in terms of effective Kohn-Sham potentials. In
this work, we numerically construct the exact electron-photon Kohn-Sham
potentials for a prototype system which consists of a trapped electron coupled
to a quantized electromagnetic mode in an optical high-Q cavity. While the
effective current that acts on the photons is known explicitly, the exact
effective potential that describes the forces exerted by the photons on the
electrons is obtained from a fixed-point inversion scheme. This procedure
allows us to uncover important beyond-mean-field features of the effective
potential which mark the breakdown of classical light-matter interactions. We
observe peak and step structures in the effective potentials, which can be
attributed solely to the quantum nature of light, i.e., they are real-space
signatures of the photons. Our findings show how the ubiquitous dipole
interaction with a classical electromagnetic field has to be modified in
real-space in order to take the quantum nature of the electromagnetic field
fully into account
Cavity Born-Oppenheimer Approximation for Correlated Electron-Nuclear-Photon Systems
In this work, we illustrate the recently introduced concept of the cavity
Born-Oppenheimer approximation for correlated electron-nuclear-photon problems
in detail. We demonstrate how an expansion in terms of conditional electronic
and photon-nuclear wave functions accurately describes eigenstates of strongly
correlated light-matter systems. For a GaAs quantum ring model in resonance
with a photon mode we highlight how the ground-state electronic
potential-energy surface changes the usual harmonic potential of the free
photon mode to a dressed mode with a double-well structure. This change is
accompanied by a splitting of the electronic ground-state density. For a model
where the photon mode is in resonance with a vibrational transition, we observe
in the excited-state electronic potential-energy surface a splitting from a
single minimum to a double minimum. Furthermore, for a time-dependent setup, we
show how the dynamics in correlated light-matter systems can be understood in
terms of population transfer between potential energy surfaces. This work at
the interface of quantum chemistry and quantum optics paves the way for the
full ab-initio description of matter-photon systems
Exact Maps in Density Functional Theory for Lattice Models
In the present work, we employ exact diagonalization for model systems on a
real-space lattice to explicitly construct the exact density-to-potential and
for the first time the exact density-to-wavefunction map that underly the
Hohenberg-Kohn theorem in density functional theory. Having the explicit
wavefunction-to- density map at hand, we are able to construct arbitrary
observables as functionals of the ground-state density. We analyze the
density-to-potential map as the distance between the fragments of a system
increases and the correlation in the system grows. We observe a feature that
gradually develops in the density-to-potential map as well as in the
density-to-wavefunction map. This feature is inherited by arbitrary expectation
values as functional of the ground-state density. We explicitly show the
excited-state energies, the excited-state densities, and the correlation
entropy as functionals of the ground-state density. All of them show this exact
feature that sharpens as the coupling of the fragments decreases and the
correlation grows. We denominate this feature as intra-system steepening. We
show that for fully decoupled subsystems the intra-system steepening transforms
into the well-known inter-system derivative discontinuity. An important
conclusion is that for e.g. charge transfer processes between localized
fragments within the same system it is not the usual inter-system derivative
discontinuity that is missing in common ground-state functionals, but rather
the differentiable intra-system steepening that we illustrate in the present
work
Measuring excitation-energy transfer with a real-time time-dependent density functional theory approach
We investigate the time an electronic excitation travels in a supermolecular
setup using a measurement process in an open quantum-system framework. The
approach is based on the stochastic Schr\"odinger equation and uses a
Hamiltonian from time-dependent density functional theory (TDDFT). It treats
electronic-structure properties and intermolecular coupling on the level of
TDDFT, while it opens a route to the description of dissipation and relaxation
via a bath operator that couples to the dipole moment of the density. Within
our study, we find that in supermolecular setups small deviations of the
electronic structure from the perfectly resonant case have only minor influence
on the pathways of excitation-energy transfer, thus lead to similar transfer
times. Yet, sizable defects cause notable slowdown of the energy spread
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