By harnessing multiple degrees of freedom (DoFs) within a single photon, controlled
quantum unitaries, such as the two-qubit controlled-NOT (cnot) gate, play a pivotal role in …

Frequency-bin encoding furnishes a compelling pathway for quantum information
processing systems compatible with established lightwave infrastructures based on fiber …

Large-scale quantum photonic circuits require integrating multiple single-photon sources,
which are typically based on spontaneous four-wave mixing (SFWM) in spiral waveguides or …

Integrated photonic microresonators have become an essential resource for generating
photonic qubits for quantum information processing, entanglement distribution and …

We demonstrate bipartite gaussian boson sampling with squeezed light in 6 mixed time-
frequency modes. Non-degenerate two-mode squeezing is generated in two time-bins from …

Transmitting an entangled state over an extended distance is crucial for the development of
quantum networks. Previous demonstrations of transmitting entangled photons over long …

Quantum teleportation is a crucial function in quantum networks. The implementation of
photonic quantum teleportation could be highly simplified by quantum photonic circuits. To …

Photons and optical circuits are among the most promising platforms for implementation of
quantum technologies, because of its potential use in quantum computing, quantum …

Frequency-bin encoding is massively parallelizable and robust for optical fiber transmission.
When coupled with an additional degree of freedom (DoF), the expansion of the Hilbert …

Transmitting an entangled state over an extended distance is crucial for the development of
quantum networks. Previous demonstrations of transmitting entangled photons over long …