In this section
@article{Alwehaibi:2025:10.1103/xw66-nqfs,
author = {Alwehaibi, Y and Mer, E and Jimenez, Machado G and Yu, S and Walmsley, I and Patel, R},
doi = {10.1103/xw66-nqfs},
journal = {Physical Review Research},
title = {Tractable protocol for detection-loophole-free bell tests over long distances},
url = {http://dx.doi.org/10.1103/xw66-nqfs},
volume = {7},
year = {2025}
}
TY - JOUR
AB - Certifying genuine nonclassical correlations over long distances is essential for device-independent quantum information. In photonic platforms, however, this remains challenging due to photon loss, which opens the detection loophole, rendering violations increasingly difficult for less-efficient detectors. Eberhard showed that using nonmaximally entangled states lowers the detection-efficiency threshold to 66.7%, but existing photonic approaches are restricted to short distances with linear transmittance scaling. Conversely, single-photon event-ready schemes extend the distance with favorable square-root scaling with channel transmittance, yet still demand detection efficiencies above 82.6%. Here, we propose the first all-photonic, heralded entanglement distribution protocol that unifies these two advances: It achieves a postselection-free violation at the Eberhard limit while preserving twin-field-like scaling. We identify the loss independent of the vacuum component amplitude of the prepared state as the source of this enhancement. Our approach addresses both resilience to loss and scalability, providing a practical route toward long-distance, loophole-free Bell tests and device-independent applications with current technology.
AU - Alwehaibi,Y
AU - Mer,E
AU - Jimenez,Machado G
AU - Yu,S
AU - Walmsley,I
AU - Patel,R
DO - 10.1103/xw66-nqfs
PY - 2025///
SN - 2643-1564
TI - Tractable protocol for detection-loophole-free bell tests over long distances
T2 - Physical Review Research
UR - http://dx.doi.org/10.1103/xw66-nqfs
VL - 7
ER -