Experimental entanglement swapping through single-photon $χ^{(2)}$ nonlinearity

Abstract: In photonic quantum information processing, quantum operations using nonlinear photon-photon interactions are vital for implementing two-qubit gates and enabling faithful entanglement swapping. However, due to the weak interaction between single photons, the all-photonic realization of such quantum operations has remained out of reach so far. Herein, we demonstrate a first entanglement swapping using sum-frequency generation (SFG) between single photons in a $\chi^{(2)}$-nonlinear optical waveguide. We show that a highly efficient, stable SFG-based Bell-state analyzer and an ultralow-dark-count superconducting single-photon detector satisfy the high signal-to-noise ratio requirement for the swapping protocol.Furthermore, the system clock is enhanced by utilizing ultrafast telecom entangled photon pair sources that operate in the GHz range. Our results confirm a lower bound 0.770(76) for the swapped state's fidelity, surpassing the classical limit of 0.5 successfully. Our findings highlight the strong potential of broadband all-single-photonic nonlinear interactions for further sophistication in long-distance quantum communication and photonic quantum computation.