In this review we focus on electronic transport through semiconductor nanostructures which
are driven by ac fields. Along the review we describe the available experimental information …

Electric transport in semiconductor superlattices is dominated by pronounced negative
differential conductivity. In this report, the standard transport theories for superlattices, ie …

Nonlinear transport phenomena are an increasingly important aspect of modern
semiconductor research. This volume deals with complex nonlinear dynamics, pattern …

In the last decade, non-linear dynamical transport in semiconductor superlattices (SLs) has
witnessed significant progress in theoretical descriptions as well as in experimentally …

We propose a driving protocol which allows us to use quantum dot arrays as quantum
simulators for 1D topological phases. We show that by driving the system out of equilibrium …

Nonlinear charge transport in semiconductor superlattices under strong electric fields
parallel to the growth direction results in rich dynamical behaviour including the formation of …

Weakly coupled semiconductor superlattices under dc voltage bias are excitable systems
with many degrees of freedom that may exhibit spontaneous chaos at room temperature and …

We analyze the dynamical evolution of the current and the charge density in a superlattice
for fixed external dc voltage in the regime of self-sustained current oscillations, using a …

Electrical transport in semiconductor superlattices is studied within a fully self-consistent
quantum transport model based on nonequilibrium Green functions, including phonon and …

A discrete drift-diffusion model is derived from a microscopic sequential tunneling model of
charge transport in weakly-coupled superlattices provided temperatures are low or high …