# High-precision nonlocal temporal correlation identification of entangled   photon pairs for quantum clock synchronization

**Authors:** Runai Quan, Ruifang Don, Xiao Xiang, Baihong Li, Tao Liu, Shougang, Zhang

arXiv: 1907.08925 · 2021-02-03

## TL;DR

This paper presents an improved method for identifying nonlocal temporal correlations in entangled photon pairs, achieving sub-picosecond precision for quantum clock synchronization applications.

## Contribution

It introduces a modified algorithm based on direct cross correlation extraction that enhances resolution and precision beyond previous FFT-based methods.

## Key findings

- Achieved 1 ps resolution dependent on time-tagging device LSB
- Realized 0.72 ps precision at 4.5 s acquisition time
- Enhanced nonlocal correlation identification for quantum synchronization

## Abstract

High-precision nonlocal temporal correlation identification in the entangled photon pairs is critical to measure the time offset between remote independent time scales for many quantum information applications. The first nonlocal correlation identification was reported in 2009, which extracts the time offset via the algorithm of iterative fast Fourier transformations (FFTs) and their inverse. The least identification resolution is restricted by the peak identification threshold of the algorithm, and thus the time offset calculation precision is limited. In this paper, an improvement for the identification is presented both in the resolution and precision via a modified algorithm of direct cross correlation extraction. A flexible resolution down to 1 ps is realized, which is only dependent on the Least Significant Bit (LSB) resolution of the time-tagging device. The attainable precision is shown mainly determined by the inherent timing jitter of the single photon detectors, the acquired pair rate and acquisition time, and a sub picosecond precision (0.72 ps) has been achieved at an acquisition time of 4.5 s. This high-precision nonlocal measurement realization provides a solid foundation for the field applications of entanglement-based quantum clock synchronization, ranging and communications.

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Source: https://tomesphere.com/paper/1907.08925