Optimized detection of high-dimensional entanglement
Abstract
Entanglement detection is one of the most conventional tasks in quantum information processing. While most experimental demonstrations of high-dimensional entanglement rely on fidelity-based witnesses, these are powerless to detect entanglement within a large class of entangled quantum states, the so-called unfaithful states. In this paper, we introduce a highly flexible automated method to construct optimal tests for entanglement detection given a bipartite target state of arbitrary dimension, faithful or unfaithful, and a set of local measurement operators. By restricting the number or complexity of the considered measurement settings, our method outputs the most convenient protocol which can be implemented using a wide range of experimental techniques such as photons, superconducting qudits, cold atoms or trapped ions. With an experimental quantum optics setup that can prepare and measure arbitrary high-dimensional mixed states, we implement some -setting protocols generated by our method. These protocols allow us to experimentally certify 2- and 3-unfaithful entanglement in 4-dimensional photonic states, some of which contain well above 50% of noise.
Cite
@article{arxiv.2011.02217,
title = {Optimized detection of high-dimensional entanglement},
author = {Xiao-Min Hu and Wen-Bo Xing and Yu Guo and Mirjam Weilenmann and Edgar A. Aguilar and Xiaoqin Gao and Bi-Heng Liu and Yun-Feng Huang and Chuan-Feng Li and Guang-Can Guo and Zizhu Wang and Miguel Navascués},
journal= {arXiv preprint arXiv:2011.02217},
year = {2021}
}
Comments
12 pages. Expanded experimental data collection, simplified theoretical description in the main text