Realizing topological superconductivity and Majorana zero modes in the laboratory is a
major goal in condensed-matter physics. In this Review, we survey the current status of this …

Recent years have seen tremendous progress in the theoretical understanding of quantum
systems driven dissipatively by coupling to different baths at their edges. This was possible …

Modern nanotechnology allows one to scale down various important devices (sensors,
chips, fibers, etc.) and thus opens up new horizons for their applications. The efficiency of …

The question whether Anderson insulators can persist to finite-strength interactions—a
scenario dubbed many-body localization—has recently received a great deal of interest. The …

Quantum transport is a diverse field, sometimes combining seemingly contradicting
concepts-quantum and classical, conduction and insulating-within a single nanodevice …

This textbook describes the physics of semiconductor nanostructures with emphasis on their
electronic transport properties. At its heart are five fundamental transport phenomena …

The properties of quasi-two-dimensional semiconductor quantum dots are reviewed.
Experimental techniques for measuring the electronic shell structure and the effect of …

The implementation of a single magnon level quantum manipulation is one of the
fundamental targets in quantum magnetism with a significant practical relevance for …

We model theoretically a two-dimensional electron gas (2DEG) covered by a
superconductor and demonstrate that topological superconducting channels are formed …

Abstract The Jaynes‐Cummings model describes the coupling between photons and a
single two‐level atom in a simplified representation of light‐matter interactions. In circuit …