Implementing graph-theoretic quantum algorithms on a silicon photonic quantum walk processor

Xiaogang Qiang; Yizhi Wang; Shichuan Xue; Renyou Ge; Lifeng Chen; Yingwen Liu; Anqi Huang; Xiang Fu; Ping Xu; Teng Yi; Fufang Xu; Mingtang Deng; Jingbo B. Wang; Jasmin D.A. Meinecke; Jonathan C.F. Matthews; Xinlun Cai; Xuejun Yang; Junjie Wu

doi:10.1126/sciadv.abb8375

Implementing graph-theoretic quantum algorithms on a silicon photonic quantum walk processor

Xiaogang Qiang, Yizhi Wang, Shichuan Xue, Renyou Ge, Lifeng Chen, Yingwen Liu, Anqi Huang, Xiang Fu, Ping Xu, Teng Yi, Fufang Xu, Mingtang Deng, Jingbo B. Wang, Jasmin D.A. Meinecke, Jonathan C.F. Matthews, Xinlun Cai, Xuejun Yang, Junjie Wu

Physics

Research output: Contribution to journal › Article › peer-review

60 Citations (Web of Science)

Abstract

Applications of quantum walks can depend on the number, exchange symmetry and indistinguishability of the particles involved, and the underlying graph structures where they move. Here, we show that silicon photonics, by exploiting an entanglement-driven scheme, can realize quantum walks with full control over all these properties in one device. The device we realize implements entangled two-photon quantum walks on any five-vertex graph, with continuously tunable particle exchange symmetry and indistinguishability. We show how this simulates single-particle walks on larger graphs, with size and geometry controlled by tuning the properties of the composite quantum walkers. We apply the device to quantum walk algorithms for searching vertices in graphs and testing for graph isomorphisms. In doing so, we implement up to 100 sampled time steps of quantum walk evolution on each of 292 different graphs. This opens the way to large-scale, programmable quantum walk processors for classically intractable applications.

Original language	English
Article number	eabb8375
Journal	Science Advances
Volume	7
Issue number	9
DOIs	https://doi.org/10.1126/sciadv.abb8375
Publication status	Published - 24 Feb 2021

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Qiang, X., Wang, Y., Xue, S., Ge, R., Chen, L., Liu, Y., Huang, A., Fu, X., Xu, P., Yi, T., Xu, F., Deng, M., Wang, J. B., Meinecke, J. D. A., Matthews, J. C. F., Cai, X., Yang, X., & Wu, J. (2021). Implementing graph-theoretic quantum algorithms on a silicon photonic quantum walk processor. Science Advances, 7(9), Article eabb8375. https://doi.org/10.1126/sciadv.abb8375

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title = "Implementing graph-theoretic quantum algorithms on a silicon photonic quantum walk processor",

abstract = "Applications of quantum walks can depend on the number, exchange symmetry and indistinguishability of the particles involved, and the underlying graph structures where they move. Here, we show that silicon photonics, by exploiting an entanglement-driven scheme, can realize quantum walks with full control over all these properties in one device. The device we realize implements entangled two-photon quantum walks on any five-vertex graph, with continuously tunable particle exchange symmetry and indistinguishability. We show how this simulates single-particle walks on larger graphs, with size and geometry controlled by tuning the properties of the composite quantum walkers. We apply the device to quantum walk algorithms for searching vertices in graphs and testing for graph isomorphisms. In doing so, we implement up to 100 sampled time steps of quantum walk evolution on each of 292 different graphs. This opens the way to large-scale, programmable quantum walk processors for classically intractable applications.",

author = "Xiaogang Qiang and Yizhi Wang and Shichuan Xue and Renyou Ge and Lifeng Chen and Yingwen Liu and Anqi Huang and Xiang Fu and Ping Xu and Teng Yi and Fufang Xu and Mingtang Deng and Wang, {Jingbo B.} and Meinecke, {Jasmin D.A.} and Matthews, {Jonathan C.F.} and Xinlun Cai and Xuejun Yang and Junjie Wu",

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AU - Qiang, Xiaogang

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AU - Xue, Shichuan

AU - Ge, Renyou

AU - Chen, Lifeng

AU - Liu, Yingwen

AU - Huang, Anqi

AU - Fu, Xiang

AU - Xu, Ping

AU - Yi, Teng

AU - Xu, Fufang

AU - Deng, Mingtang

AU - Wang, Jingbo B.

AU - Meinecke, Jasmin D.A.

AU - Matthews, Jonathan C.F.

AU - Cai, Xinlun

AU - Yang, Xuejun

AU - Wu, Junjie

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N2 - Applications of quantum walks can depend on the number, exchange symmetry and indistinguishability of the particles involved, and the underlying graph structures where they move. Here, we show that silicon photonics, by exploiting an entanglement-driven scheme, can realize quantum walks with full control over all these properties in one device. The device we realize implements entangled two-photon quantum walks on any five-vertex graph, with continuously tunable particle exchange symmetry and indistinguishability. We show how this simulates single-particle walks on larger graphs, with size and geometry controlled by tuning the properties of the composite quantum walkers. We apply the device to quantum walk algorithms for searching vertices in graphs and testing for graph isomorphisms. In doing so, we implement up to 100 sampled time steps of quantum walk evolution on each of 292 different graphs. This opens the way to large-scale, programmable quantum walk processors for classically intractable applications.

AB - Applications of quantum walks can depend on the number, exchange symmetry and indistinguishability of the particles involved, and the underlying graph structures where they move. Here, we show that silicon photonics, by exploiting an entanglement-driven scheme, can realize quantum walks with full control over all these properties in one device. The device we realize implements entangled two-photon quantum walks on any five-vertex graph, with continuously tunable particle exchange symmetry and indistinguishability. We show how this simulates single-particle walks on larger graphs, with size and geometry controlled by tuning the properties of the composite quantum walkers. We apply the device to quantum walk algorithms for searching vertices in graphs and testing for graph isomorphisms. In doing so, we implement up to 100 sampled time steps of quantum walk evolution on each of 292 different graphs. This opens the way to large-scale, programmable quantum walk processors for classically intractable applications.

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Implementing graph-theoretic quantum algorithms on a silicon photonic quantum walk processor

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