Visually quantifying single-qubit quantum memory
Abstract
To store quantum information, quantum memory plays a central intermediate ingredient in a network. The minimal criterion for a reliable quantum memory is the maintenance of the entangled state, which can be described by the non-entanglement-breaking (non-EB) channel. In this work, we show that all single-qubit quantum memory can be quantified without trusting input state generation. In other words, we provide a semi-device-independent approach to quantify all single-qubit quantum memory. More specifically, we apply the concept of the two-qubit quantum steering ellipsoids to a single-qubit quantum channel and define the channel ellipsoids. An ellipsoid can be constructed by visualizing finite output states within the Bloch sphere. Since the Choi-Jamio{\l}kowski state of a channel can all be reconstructed from geometric data of the channel ellipsoid, a reliable quantum memory can be detected. Finally, we visually quantify the single-qubit quantum memory by observing the volume of the channel ellipsoid.
Cite
@article{arxiv.2312.06939,
title = {Visually quantifying single-qubit quantum memory},
author = {Wan-Guan Chang and Chia-Yi Ju and Guang-Yin Chen and Yueh-Nan Chen and Huan-Yu Ku},
journal= {arXiv preprint arXiv:2312.06939},
year = {2023}
}
Comments
9 pages, 5 figures