Optically addressable solid-state spin defects are promising candidates for storing and
manipulating quantum information using their long coherence ground-state manifold; …

Quantum technology has grown out of quantum information theory and now provides a
valuable tool that researchers from numerous fields can add to their toolbox of research …

In the last two decades, bulk, homoepitaxial, and heteroepitaxial growth of silicon carbide
(SiC) has witnessed many advances, giving rise to electronic devices widely used in high …

This paper summarizes recent studies identifying key qubit systems in silicon carbide (SiC)
for quantum sensing of magnetic, electric fields, and temperature at the nano and …

Spin defects in silicon carbide have the advantage of exceptional electron spin coherence
combined with a near-infrared spin-photon interface, all in a material amenable to modern …

In current long-distance communications, classical information carried by large numbers of
particles is intrinsically robust to some transmission losses but can, therefore, be …

Quantum systems combining indistinguishable photon generation and spin-based quantum
information processing are essential for remote quantum applications and networking …

Understanding the capture of charge carriers by colour centres in semiconductors is
important for the development of novel forms of sensing and quantum information …

Controlling and manipulating individual quantum systems in solids underpins the growing
interest in the development of scalable quantum technologies. Recently, hexagonal boron …

Reliable single-photon emission is crucial for realizing efficient spin-photon entanglement
and scalable quantum information systems. The silicon vacancy (V Si) in 4H-SiC is a …