Silicon T centers present the promising possibility of generating optically active spin qubits
in an all-silicon device. However, these color centers exhibit long excited state lifetimes and …

Individual spins that are coupled to telecommunication photons offer unique promise for
distributed quantum information processing once a coherent and efficient spin–photon …

Color centers in Si could serve as both efficient quantum emitters and quantum memories
with long coherence times in an all-silicon platform. Of the various known color centers, the T …

Miniaturized and rationally assembled nanostructures exhibit extraordinarily distinct physical
properties beyond their individual units. This review will focus on structured small-scale …

Novel T centers in silicon hold great promise for quantum networking applications due to
their telecom band optical transitions and the long-lived ground state electronic spins. An …

Silicon is the ideal material for building electronic and photonic circuits at scale. Integrated
photonic quantum technologies in silicon offer a promising path to scaling by leveraging …

Quantum emitters in solid-state crystals have recently attracted a great deal of attention due
to their simple applicability in optical quantum technologies. The polarization of single …

Artificial atoms in solids are leading candidates for quantum networks, scalable quantum
computing, and sensing, as they combine long-lived spins with mobile photonic qubits …

Generating single photons on demand in silicon is a challenge to the scalability of silicon-on-
insulator integrated quantum photonic chips. While several defects acting as artificial atoms …

Silicon-based quantum emitters are candidates for large-scale qubit integration due to their
single-photon emission properties and potential for spin-photon interfaces with long spin …