A manufacturable platform for photonic quantum computing
Abstract
Whilst holding great promise for low noise, ease of operation and networking, useful photonic quantum computing has been precluded by the need for beyond-state-of-the-art components, manufactured by the millions. Here we introduce a manufacturable platform for quantum computing with photons. We benchmark a set of monolithically-integrated silicon photonics-based modules to generate, manipulate, network, and detect photonic qubits, demonstrating dual-rail photonic qubits with 99.98\% 0.01\% state preparation and measurement fidelity, Hong-Ou-Mandel quantum interference between independent photon sources with 99.50\%0.25\% visibility, two-qubit fusion with 99.22\%0.12\% fidelity, and a chip-to-chip qubit interconnect with 99.72\%0.04\% fidelity, not accounting for loss. In addition, we preview a selection of next generation technologies, demonstrating low-loss silicon nitride waveguides and components, fabrication-tolerant photon sources, high-efficiency photon-number-resolving detectors, low-loss chip-to-fiber coupling, and barium titanate electro-optic phase shifters.
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