A future quantum network will consist of quantum processors that are connected by quantum
channels, just like conventional computers are wired up to form the Internet. In contrast to …

With the ability to transfer and process quantum information, large-scale quantum networks
will enable a suite of fundamentally new applications, from quantum communications to …

Solid-state single-photon sources are central building blocks in quantum information
processing. Atomically thin crystals have emerged as sources of nonclassical light; however …

Large-scale quantum communication networks require quantum repeaters due to the signal
attenuation in optical fibers. Ideal quantum repeater nodes efficiently link a quantum memory …

Coupling between a single quantum emitter and an optical cavity presents a key capability
for future quantum networking applications. Here, we explore interactions between …

High-performance optical quantum memories serving as quantum nodes are crucial for the
distribution of remote entanglement and the construction of large-scale quantum networks …

Open-access microcavities are a powerful tool to enhance light–matter interactions for solid-
state quantum and nanosystems and are key to advance applications in quantum …

Open microcavities offer great potential for the exploration and utilization of efficient spin-
photon interfaces with Purcell-enhanced quantum emitters thanks to their large spectral and …

We describe an apparatus for the implementation of hybrid optomechanical systems at 4 K.
The platform is based on a high-finesse, micrometer-scale fiber Fabry–Perot cavity, which …

Single-photon emitters integrated in optical microcavities are key elements in quantum com
munication applications. However, optimizing their emission properties and achieving …