Recent progress in applying complex network theory to problems in quantum information
has resulted in a beneficial cross-over. Complex network methods have successfully been …

These are exciting times for quantum physics as new quantum technologies are expected to
soon transform computing at an unprecedented level. Simultaneously network science is …

The intriguing many-body phases of quantum matter arise from the interplay of particle
interactions, spatial symmetries, and external fields. Generating these phases in an …

Transverse spin angular momentum is an inherent feature of evanescent waves which may
have applications in nanoscale optomechanics, spintronics, and quantum information …

We experimentally investigate topological phenomena in one-dimensional discrete-time
photonic quantum walks using a combination of methods. We first detect winding numbers of …

Controlling transport in quantum systems holds the key to many promising quantum
technologies. Here we review the power of symmetry as a resource to manipulate quantum …

The control of exciton transport in organic materials is of fundamental importance for the
development of efficient light-harvesting systems. This transport is easily deteriorated by …

Determining community structure is a central topic in the study of complex networks, be it
technological, social, biological or chemical, static or in interacting systems. In this paper, we …

We exploit controlled breaking of time-reversal symmetry to realize coherent routing of
quantum information in spin networks. The key component of our scheme is a spin triangle …

We address routing of classical and quantum information over quantum network and show
how to exploit chirality (directionality) to achieve nearly optimal and robust transport. In …