Quantum Advantage: A Single Qubit's Experimental Edge in Classical Data Storage
Abstract
We implement an experiment on a photonic quantum processor establishing efficacy of the elementary quantum system in classical information storage. The advantage is established by considering a class of simple bipartite games played with the communication resource qubit and classical bit (c-bit), respectively. Conventional wisdom, supported by the no-go theorems of Holevo and Frenkel-Weiner, suggests that such a quantum advantage is unattainable when the sender and receiver share randomness or classical correlations. However, our results reveal a quantum advantage in a scenario devoid of any shared randomness. Our experiment involves the development of a variational triangular polarimeter, enabling the realization of positive operator value measurements crucial for establishing the targeted quantum advantage. Beyond showcasing a robust communication advantage with a single qubit, our work paves the way for immediate applications in near-term quantum technologies. It provides a semi-device-independent certification scheme for quantum encoding-decoding systems and offers an efficient method for information loading and transmission in quantum networks.
Cite
@article{arxiv.2403.02659,
title = {Quantum Advantage: A Single Qubit's Experimental Edge in Classical Data Storage},
author = {Chen Ding and Edwin Peter Lobo and Mir Alimuddin and Xiao-Yue Xu and Shuo Zhang and Manik Banik and Wan-Su Bao and He-Liang Huang},
journal= {arXiv preprint arXiv:2403.02659},
year = {2026}
}
Comments
Accepted for publication in Phys. Rev. Lett