English

Experimental Quantum Switching for Exponentially Superior Quantum Communication Complexity

Quantum Physics 2019-04-01 v2

Abstract

Finding exponential separation between quantum and classical information tasks is like striking gold in quantum information research. Such an advantage is believed to hold for quantum computing but is proven for quantum communication complexity. Recently, a novel quantum resource called the quantum switch---which creates a coherent superposition of the causal order of events, known as quantum causality---has been harnessed theoretically in a new protocol providing provable exponential separation. We experimentally demonstrate such an advantage by realizing a superposition of communication directions for a two-party distributed computation. Our photonic demonstration employs dd-dimensional quantum systems, qudits, up to d=213d=2^{13} dimensions and demonstrates a communication complexity advantage, requiring less than (0.696±0.006)(0.696 \pm 0.006) times the communication of any causally ordered protocol. These results elucidate the crucial role of the coherence of communication direction in achieving the exponential separation for the one-way processing task, and open a new path for experimentally exploring the fundamentals and applications of advanced features of indefinite causal structures.

Keywords

Cite

@article{arxiv.1810.10238,
  title  = {Experimental Quantum Switching for Exponentially Superior Quantum Communication Complexity},
  author = {Kejin Wei and Nora Tischler and Si-Ran Zhao and Yu-Huai Li and Juan Miguel Arrazola and Yang Liu and Weijun Zhang and Hao Li and Lixing You and Zhen Wang and Yu-Ao Chen and Barry C. Sanders and Qiang Zhang and Geoff J. Pryde and Feihu Xu and Jian-Wei Pan},
  journal= {arXiv preprint arXiv:1810.10238},
  year   = {2019}
}

Comments

Accepted by Phys. Rev. Lett

R2 v1 2026-06-23T04:50:55.677Z