Defects with associated electron and nuclear spins in solid-state materials have a long
history relevant to quantum information science that goes back to the first spin echo …

Spins in solids or in molecules possess discrete energy levels, and the associated quantum
states can be tuned and coherently manipulated by means of external electromagnetic …

Quantum sensing using optically addressable atomic-scale defects, such as the nitrogen-
vacancy (NV) center in diamond, provides new opportunities for sensitive and highly …

The realization of quantum networks critically depends on establishing efficient, coherent
light-matter interfaces. Optically active spins in diamond have emerged as promising …

Coherent interfaces between optical photons and long-lived matter qubits form a key
resource for a broad range of quantum technologies. Cavity quantum electrodynamics …

Atomic defects in wide-bandgap materials, such as the nitrogen-vacancy (NV) color center in
diamond, show considerable promise for the development of a new generation of quantum …

We demonstrate the on-demand creation and positioning of photon emitters in atomically
thin MoS2 with very narrow ensemble broadening and negligible background …

The realization of quantum information processing would disrupt the status quo in the realm
of computation; the extraordinary power of a hypothetical quantum computer motivates …

Structuring materials with atomic precision is the ultimate goal of nanotechnology and is
becoming increasingly relevant as an enabling technology for quantum …

The realization of scalable systems for quantum information processing and networking is of
utmost importance to the quantum information community. However, building such systems …