Defect engineering in diamond for magnetic field mapping and gradiometry
Lead Research Organisation:
University of Oxford
Department Name: Materials
Abstract
Nitrogen-vacancy defects in diamond have generated enormous interest in recent years for their highly coherent spin properties and convenient optical interface. Magnetometry using the electron spin in an ensemble of NV- defect has been shown to be capable of detecting fields of <1 pT Hz-1/2 such that their use as quantum field sensors is generating significant industrial interest. Companies known to be building commercial magnetometry systems with NV centres include Bosch (navigation systems), and several organisations are developing NV-based magnetic imaging systems with ~10nm resolution for biological and physical sciences.
NV centres can be produced by generation of vacancies followed by thermal annealing to allow the vacancies to diffuse in the crystal and 'bind' with a substitutional nitrogen atom. In the past two years we have shown that laser processing of materials using adaptive aberration correction provides a highly controlled means of generating vacancies in a desired position in the crystal. Upon subsequent annealing the vacancies diffuse ~100 nm such that NV centres are produced with high probability in the desired location. Success probability of single NV generation in current experiments is around 30%. With iterative processing it should be possible to produce regular 3D grids of single NV centres for advanced magnetometry applications.
The Project: The student will develop controlled 3D arrays of single NV centres using laser processing in Martin Booth's group in the department of Engineering. Samples will be characterised using photoluminescence spectroscopy and optically detected magnetic resonance in Jason Smith's group in the Department of Materials. Samples with cubic arrays of NV centres will be targeted. We will measure the electron spin coherence times of the NV centres to assess their suitability for magnetometry. The best samples will be used to demonstrate 3D magnetic field mapping and gradiometry.
The student will benefit from working within two groups involved in the NQIT Hub and will receive extensive training in laser processing, defect characterisation and magnetometry. They will work with NQIT postdocs Patrick Salter (Engineering) and Sam Johnson (Materials). They will gain in-depth training in diamond by attending modules of the Centre for Doctoral Training in Diamond Science and Technology. We will arrange close interaction between the student and Element Six to optimise the materials towards user applications.
The project falls under the theme of Quantum Technologies.
NV centres can be produced by generation of vacancies followed by thermal annealing to allow the vacancies to diffuse in the crystal and 'bind' with a substitutional nitrogen atom. In the past two years we have shown that laser processing of materials using adaptive aberration correction provides a highly controlled means of generating vacancies in a desired position in the crystal. Upon subsequent annealing the vacancies diffuse ~100 nm such that NV centres are produced with high probability in the desired location. Success probability of single NV generation in current experiments is around 30%. With iterative processing it should be possible to produce regular 3D grids of single NV centres for advanced magnetometry applications.
The Project: The student will develop controlled 3D arrays of single NV centres using laser processing in Martin Booth's group in the department of Engineering. Samples will be characterised using photoluminescence spectroscopy and optically detected magnetic resonance in Jason Smith's group in the Department of Materials. Samples with cubic arrays of NV centres will be targeted. We will measure the electron spin coherence times of the NV centres to assess their suitability for magnetometry. The best samples will be used to demonstrate 3D magnetic field mapping and gradiometry.
The student will benefit from working within two groups involved in the NQIT Hub and will receive extensive training in laser processing, defect characterisation and magnetometry. They will work with NQIT postdocs Patrick Salter (Engineering) and Sam Johnson (Materials). They will gain in-depth training in diamond by attending modules of the Centre for Doctoral Training in Diamond Science and Technology. We will arrange close interaction between the student and Element Six to optimise the materials towards user applications.
The project falls under the theme of Quantum Technologies.
Organisations
People |
ORCID iD |
Jason Smith (Primary Supervisor) | |
Benjamin Griffiths (Student) |
Publications
Chen Y
(2019)
Laser writing of individual nitrogen-vacancy defects in diamond with near-unity yield
in Optica
Studentship Projects
Project Reference | Relationship | Related To | Start | End | Student Name |
---|---|---|---|---|---|
EP/N509711/1 | 30/09/2016 | 29/09/2021 | |||
1944822 | Studentship | EP/N509711/1 | 30/09/2017 | 28/09/2021 | Benjamin Griffiths |
Description | A new engineering technique has been developed in which a femtosecond laser is used to create and diffuse vacancies within diamond. These act like artificial atoms and can be used as qubits. Furthermore, the physics of non-linear light matter interaction under very intense light has been studied with development of a differential equation model. This has increased knowledge of fundamental science. |
Exploitation Route | To probe a fundamental understanding of non-linear light matter interaction in a general material and to put to use the engineering technique to develop quantum technologies |
Sectors | Digital/Communication/Information Technologies (including Software) Electronics Government Democracy and Justice Security and Diplomacy |
URL | https://www.osapublishing.org/optica/fulltext.cfm?uri=optica-6-5-662&id=412315 |
Title | Laser writing of colour centres in crystals |
Description | An engineering technique enabling the deterministic creation of colour centres in crystals by us of a femtosecond laser. Single pulses of the laser create vacancies and a train of pulses allow vacancies to diffuse. Fluorescence monitoring allows to continue processing until the desired defect is formed |
IP Reference | GB1808367.5 |
Protection | Patent application published |
Year Protection Granted | 2018 |
Licensed | No |
Impact | Currently only an academic paper |