Platform-agnostic components built for real-world quantum systems.
We make quantum connectivity practical at scale. Through high-multiplexing, AI-driven design tools, and telecom-ready hardware, we transform laboratory prototypes into modular, deployable network nodes—enabling interoperable platforms that amplify the capability of every connected quantum device.
Quantum routers and repeaters extend the reach of quantum communication by preserving fragile quantum states over long distances. They perform entanglement distribution, purification, and swapping to connect distant nodes and maintain high-fidelity quantum links. By coordinating quantum memories, entanglement generation, and classical control, these devices form the scalable backbone required for wide-area quantum networks and future quantum internet infrastructure.
Our entangled photon pair sources generate high-rate, on-demand entanglement with well-controlled spectral and temporal properties. Unlike probabilistic sources, they deliver reproducible photon pairs synchronized to network operations, enabling time-bin, polarization, or frequency-bin entanglement tailored to specific protocols. These sources are essential for quantum repeaters, secure communication systems, distributed quantum computing, and any architecture that relies on reliable, multiplexed entanglement generation.
Optical interfaces bridge the gap between diverse quantum devices, enabling quantum states to move seamlessly across memories, quantum processors, and long-distance telecom links. They perform wavelength conversion and mode shaping to ensure that photons produced by one system can be reliably received and processed by another. By enabling compatibility across otherwise incompatible devices, these interfaces make heterogeneous quantum networks possible.
Spectral and spatial multiplexing enables many entangled channels to operate in parallel, dramatically increasing network throughput while mitigating loss over long distances.
Local quantum logic with onboard entanglement purification allows each node to correct errors and maintain high-fidelity links, providing the foundation for scalable, fault-tolerant quantum networking.
Interoperability across different quantum modalities is enabled by a universal quantum bus that bridges differing operating frequencies and provides a shared telecom backbone for connecting heterogeneous quantum devices.
Spectral and spatial multiplexing enables many entangled channels to operate in parallel, dramatically increasing network throughput while mitigating loss over long distances.
Partner with us in shaping the future of quantum networking, or join the team building the systems that power it.