Related papers: Fusion for High-Dimensional Linear Optical Quantum Computing with Improved Success Probability

Fusion for High-Dimensional Linear Optical Quantum Computing with Improved Success Probability

URL: http://arxiv.org/abs/2505.16816v1
Date: Thu, 22 May 2025 15:52:03 GMT
Title: Fusion for High-Dimensional Linear Optical Quantum Computing with Improved Success Probability
Authors: Gözde Üstün, Eleanor G. Rieffel, Simon J. Devitt, Jason Saied,
Abstract summary: We discuss the construction of the required $(d-2)$-qudit ancillary state using a silicon spin qudit ancilla coupled to a microwave cavity through time-bin multiplexing.<n>We use this method to analyze and improve several different circuits for high-dimensional Type-II fusion.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Type-II fusion is a probabilistic entangling measurement that is essential to measurement-based linear optical quantum computing and can be used for quantum teleportation more broadly. However, it remains under-explored for high-dimensional qudits. Our main result gives a Type-II fusion protocol with proven success probability approximately $2/d^2$ for qudits of arbitrary dimension $d$. This generalizes a previous method which only applied to even-dimensional qudits. We believe this protocol to be the most efficient known protocol for Type-II fusion, with the $d=5$ case beating the previous record by a factor of approximately $723$. We discuss the construction of the required $(d-2)$-qudit ancillary state using a silicon spin qudit ancilla coupled to a microwave cavity through time-bin multiplexing. We then introduce a general framework of extra-dimensional corrections, a natural technique in linear optics that can be used to non-deterministically correct non-maximally-entangled projections into Bell measurements. We use this method to analyze and improve several different circuits for high-dimensional Type-II fusion and compare their benefits and drawbacks.

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