From atomic-scale imaging to quantum fault-tolerance with spins in diamond

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doi:10.4233/uuid:cce8dbcb-cfc2-4fa2-b78b-99c803dee02d

From atomic-scale imaging to quantum fault-tolerance with spins in diamond

Doctoral Thesis (2021)

Author(s)

Mohamed Abobeih (TU Delft - QID/Taminiau Lab)

Contributor(s)

R. Hanson – Promotor (TU Delft - QID/Hanson Lab)

T.H. Taminiau – Copromotor (TU Delft - QID/Taminiau Lab)

Research Group

QID/Taminiau Lab

DOI related publication

https://doi.org/10.4233/uuid:cce8dbcb-cfc2-4fa2-b78b-99c803dee02d Final published version

To reference this document use

https://doi.org/10.4233/uuid:cce8dbcb-cfc2-4fa2-b78b-99c803dee02d

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Publication Year

2021

Language

English

Research Group

QID/Taminiau Lab

ISBN (electronic)

978-90-8593-461-5

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596

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Abstract

Owing to its exceptional spin properties and bright spin-photon interface, the nitrogenvacancy (NV) center in diamond has emerged as a promising platformfor quantum science and technology, including quantum communication, quantum computation and quantum sensing. In this thesis we develop novel methods for atomic-scale imaging and high-fidelity control of complex nuclear-spin systems coupled to the electron spin of an NV center in diamond. This well-controlled quantum system provides new opportunities in quantum sensing, quantum information processing, and may also form the building block of a large-scale quantum network, one of the key goals in quantum technology.

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