Lightsynq Unveils Quantum Interconnects to Scale Up Quantum Computing

Lightsynq, a cutting-edge technology company, has launched with a mission to enable quantum computers to scale to commercially useful sizes. Founded by a team of experts in quantum physics, Lightsynq aims to overcome the scaling problem faced by current quantum computing systems. The company’s solution lies in its innovative quantum interconnects that can link multiple limited-scale devices into a modular, full-scale quantum computer. This approach is built on years of research and utilizes quantum memories based on diamond color centers, allowing for compatibility with various quantum hardware platforms.

Lightsynq’s technology has already demonstrated the first-ever memory-enhanced quantum link based on color-centers in diamond photonic circuits, showcasing its potential to accelerate the quantum industry’s timeline to commercial impact. The company has secured $18M in Series A funding from investors including Cerberus Capital Management, Murata Electronics North America Inc., and In-Q-Tel (IQT), among others. With this support, Lightsynq plans to build the first quantum interconnect prototypes and collaborate with leading quantum computing companies to unlock the full potential of quantum computing.

Unlocking the Potential of Quantum Computing: The Role of Quantum Interconnects

Quantum computing has the potential to revolutionize various industries, from drug and material design to solving complex optimization problems. However, current quantum computers face substantial scale-up challenges before they can reach their full potential. One of the main obstacles is connecting multiple limited-scale devices into a modular, full-scale quantum computer. This is where quantum interconnects come in – a technology that enables the linking of several small-scale devices to create a larger, more powerful system.

The Solution: Quantum Interconnects Based on Color Centers in Diamond

Lightsynq, a company founded by experts in quantum physics and business, has developed a novel approach to quantum interconnects based on diamond color centers. Their technology uses photonic integrated circuits (PICs) to achieve high-fidelity, high-efficiency interactions between single photons and the electron qubit of the color center. This enables the creation of compact chips that can host several hundred quantum memory channels in parallel.

Diamond-based PICs offer important advantages, including the ability to perform universal quantum logic operations on the quantum memory register, enabling in-memory Bell-state measurements for entanglement swapping. Additionally, the “heralded” memory operation automatically detects the successful storage of a photon in the memory, allowing for high-fidelity connections despite large losses associated with extracting photons from a quantum computer.

The Broader Quantum Computing Landscape

Quantum computing is advancing rapidly, with many promising technologies that each have their own strengths. However, all approaches need to scale rapidly to reach their full potential. Lightsynq’s optical quantum interconnects provide the scaling pathway needed to reach commercial utility, enabling quantum computing companies to focus on building powerful error-corrected systems.

As the capabilities of these interconnects expand, they could also connect quantum computers directly to end users and other devices over long-distance quantum networks, unlocking new possibilities such as secure multi-party computation and quantum-assisted sensing.

The Future of Quantum Interconnects

Lightsynq has recently closed an $18M Series A funding round led by Cerberus Capital Management, with participation from several prominent investors. This funding will go directly toward building the first quantum interconnect prototypes, which will be used to help leading quantum computing companies scale to multi-module systems for the first time.

The company plans to work closely with top quantum companies to accelerate scaling and unlock the full potential of quantum computing. With their technology, they aim to bring about a world transformed by quantum technologies, where secure communication, advanced sensing, and unprecedented computational power become a reality.