At present, metal–molecular tunnel junctions are recognized as important active elements in
molecular electronics. This gives a strong motivation to explore physical mechanisms …

We review recent progress in the theoretical description of correlation and quantum
fluctuation phenomena in charge transport through single molecules, quantum dots and …

The aim of this book is to introduce the basic elements of the scattering matrix approach to
transport phenomena in dynamical quantum systems of non-interacting electrons. This …

The controlled and accurate emission of coherent electronic wave packets is of prime
importance for future applications of nanoscale electronics. Here, we present a theoretical …

We calculate the mesoscopic admittance G (ω) of a double quantum dot (DQD), which can
be measured directly using microwave techniques. This quantity reveals spectroscopic …

We study relaxation dynamics in a strongly interacting two-site Fermi-Hubbard model that is
induced by coupling each site to a local fermionic bath. To derive the proper form of the …

We study geometric energy transport in a slowly driven single-level quantum dot weakly
coupled to electronic contacts and with strong on-site interaction, which can be either …

We analyze the dynamics of a single-level quantum dot with Coulomb interaction, weakly
tunnel coupled to an electronic reservoir, after it has been brought out of equilibrium, eg, by …

We derive formal expressions of time-dependent energy and heat currents through a
nanoscopic device using the Keldysh nonequilibrium Green function technique. Numerical …

We extend the recently developed causal superfermion approach to the real-time
diagrammatic transport theory to time-dependent decay problems. Its usefulness is …