High-fidelity, quasi-deterministic entanglement generation using phase-matched spectral islands in a zero-added-loss multiplexing architecture (2507.14427v1)

Abstract: While photonic entanglement generation and distribution are well developed, their demonstrated rates are far below what is needed for a quantum internet. The present paper proposes and analyzes a scheme for spectral multiplexing that provides entanglement-distribution rates well in excess of the state of the art. It builds on the idea presented by Chen~\emph{et al}.~[Phys. Rev. Appl. {\bf 19}, 054209 (2023)], who proposed zero-added-loss multiplexing (ZALM) as a means for high-fidelity, quasi-deterministic entanglement generation. Unfortunately, Chen \emph{et al}.'s ZALM requires a large number (800) of spectral channels to achieve its claimed high-fidelity, quasi-deterministic, high-rate entanglement generation. Our modified version of ZALM affords major performance improvements over the original. It draws on Morrison~\emph{et al}.~[APL Photon. {\bf 7}, 066102 (2022)], who domain engineered a $\chi^{(2)}$ crystal to realize a biphoton wave function with 8 discrete and spectrally-factorable frequency bins. Our ZALM SPDCs each have a modest number ($N_I\ll$ 800) of these phase-matched spectral islands each generating two-mode squeezed-vacuum states, permitting our analysis, unlike Chen~\emph{et al.}'s, to account for multipairs of all orders, losses in the partial BSM, and propagation losses en route to the receivers. A major innovation in our proposal is to employ both same-island heralding and cross-island heralding, which allows the entanglement-delivery rate to scale as $N_I^2$ rather than $N_I$ in the weak squeezing regime required for the reception of photon pairs with a high Bell-state fidelity under realistic losses. This heralding scheme uses an order of magnitude fewer spectral channels, which may enable near-term implementations of satellite-to-ground or fiber-optic based ZALM architectures.