Diamond is of great importance for scientific and practical applications. It is the hardest
natural material and holds potential applications in mechanics, electronics and photonics …

Silicon-vacancy (SiV) centers in diamond are gaining an increased interest for application,
such as in quantum technologies and sensing. Due to the strong luminescence …

A robust technique is introduced for vector magnetometry based on polarimetry and optically
detected magnetic resonance of ensembles of negatively charged nitrogen‐vacancy (NV–) …

Group IV vacancy color centers in diamond are promising spin-photon interfaces with strong
potential for applications in photonic quantum technologies. Reliable methods for controlling …

Color centers in diamond, silicon carbide, and related materials have recently emerged as
one of the most promising platforms for quantum technology applications. These optically …

Single-color centers in thin polycrystalline diamond membranes allow the platform to be
used in integrated quantum photonics, hybrid quantum systems, and other complex …

Conspectus Diamond, a wide bandgap semiconductor, has captivated researchers for
decades due to its exceptional properties. While p-type doping has dominated the field, the …

At the heart of the flourishing field of machine learning potentials are graph neural networks,
where deep learning is interwoven with physics-informed machine learning (PIML) …

The controlled creation of quantum emitters in diamond represents a major research effort in
the fabrication of single‐photon devices. Here, the scalable production of silicon‐vacancy …

Understanding the properties of lithium vacancy, LiCV, defects in diamond is crucial for
optimizing diamond-based semiconductor performance and unlocking its full potential in …