Journal article

Fault-tolerant quantum computation without distillation on a 2D device

Abstract:: We show how looped pipeline architectures—which use short-range shuttling of physical qubits to achieve bounded non-local connectivity—can efficiently implement the fault-tolerant non-Clifford gate between 2D surface codes described in (Sci. Adv. 6, eaay4929 (2020)). The shuttling schedule required is only marginally more complex than is required for implementing the standard 2D surface code in this architecture. We compare the resource cost 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 largely due to the relatively low performance of the just-in-time decoder used in the procedure, which necessitates very large code distances in order to achieve suitably low logical error rates. We argue that, as little attention has been given to the study and optimisation of these decoders, there are potentially significant improvements to be made in this area.

Publication status:: Published

Peer review status:: Peer reviewed

Actions

Email

Email this record

Send the bibliographic details of this record to your email address.

Your Email
Please enter the email address that the record information will be sent to.

-
Your message (optional)
Please add any additional information to be included within the email.
Share
Cite

Cite this record

APA Style

Scruby, T. R., Nemoto, K., & Cai, Z. (2025). Fault-tolerant quantum computation without distillation on a 2D device. Npj Quantum Information, 11(1).

MLA Style

Scruby, TR, et al. “Fault-Tolerant Quantum Computation without Distillation on a 2D Device.” Npj Quantum Information, vol. 11, no. 1, 2025.

Chicago Style

Scruby, TR, K Nemoto, and Z Cai. 2025. “Fault-Tolerant Quantum Computation without Distillation on a 2D Device.” Npj Quantum Information 11 (1).
Print

Access Document

Files:: Scruby_et_al_2025_Fault-tolerant_quantum_computation.pdf

(Preview, Version of record, pdf, 1.9MB, Terms of use)

Scruby_et_al_2025_Fault-tolerant_quantum_computation_Supplemen...

(Preview, Other, pdf, 3.5MB, Terms of use)

Publisher copy:: 10.1038/s41534-025-01133-7

Authors

+ Scruby, TR More by this author

Role:: Author

+ Nemoto, K More by this author

Role:: Author

+ Cai, Z More by this author

Institution:: University of Oxford
Division:: SSD
Department:: International Development
Sub department:: Refugee Studies Centre
Role:: Author

+ Japan Science and Technology Agency More from this funder

Funder identifier:: https://ror.org/00097mb19

+ Engineering and Physical Sciences Research Council More from this funder

Funder identifier:: https://ror.org/0439y7842

Publisher:: Nature Research
Journal:: npj Quantum Information More from this journal
Volume:: 11
Issue:: 1
Article number:: 189
Publication date:: 2025-11-28
Acceptance date:: 2025-10-22
DOI:: 10.1038/s41534-025-01133-7
EISSN:: 2056-6387
ISSN:: 2056-6387

Language:: English
Pubs id:: 2347960
UUID:: uuid_3470e844-a4bf-45e0-a01c-a8f9f3f3fcd3
Local pid:: pubs:2347960
Source identifiers:: 3518123
Deposit date:: 2025-11-28
ARK identifier:: ark:/29072/ora_3470e844a4bf45e0a01ca8f9f3f3fcd3

Terms of use

Copyright date:: 2025

Licence:: CC Attribution (CC BY)

Views and Downloads

About views and downloads

If you are the owner of this record, you can report an update to it here: Report update to this record

TO TOP