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Main Authors: Scruby, Thomas R., Nemoto, Kae, Cai, Zhenyu
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.12529
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author Scruby, Thomas R.
Nemoto, Kae
Cai, Zhenyu
author_facet Scruby, Thomas R.
Nemoto, Kae
Cai, Zhenyu
contents We show how looped pipeline architectures - which use short-range shuttling of physical qubits to achieve a finite amount of non-local connectivity - can be used to efficiently implement the fault-tolerant non-Clifford gate between 2D surface codes described in (Sci. Adv. 6, eaay4929 (2020)). The shuttling schedule needed to implement this gate is only marginally more complex than is required for implementing the standard 2D surface code in this architecture. We compare the resource cost of this operation with the cost of magic state distillation and find that, at present, this comparison is heavily in favour of distillation. The high cost of the non-Clifford gate is almost entirely due to the relatively low performance of the just-in-time decoder used as part of this process, which necessitates very large code distances in order to achieve suitably low logical error rates. We argue that, as very little attention has previously been given to the study and optimisation of these decoders, there are potentially significant improvements to be made in this area.
format Preprint
id arxiv_https___arxiv_org_abs_2412_12529
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Fault-tolerant Quantum Computation without Distillation on a 2D Device
Scruby, Thomas R.
Nemoto, Kae
Cai, Zhenyu
Quantum Physics
We show how looped pipeline architectures - which use short-range shuttling of physical qubits to achieve a finite amount of non-local connectivity - can be used to efficiently implement the fault-tolerant non-Clifford gate between 2D surface codes described in (Sci. Adv. 6, eaay4929 (2020)). The shuttling schedule needed to implement this gate is only marginally more complex than is required for implementing the standard 2D surface code in this architecture. We compare the resource cost of this operation with the cost of magic state distillation and find that, at present, this comparison is heavily in favour of distillation. The high cost of the non-Clifford gate is almost entirely due to the relatively low performance of the just-in-time decoder used as part of this process, which necessitates very large code distances in order to achieve suitably low logical error rates. We argue that, as very little attention has previously been given to the study and optimisation of these decoders, there are potentially significant improvements to be made in this area.
title Fault-tolerant Quantum Computation without Distillation on a 2D Device
topic Quantum Physics
url https://arxiv.org/abs/2412.12529