Development of a High Flux Accelerator-Driven Neutron Irradiation Facility for Nuclear Plant Materials and Applied Neutron Science
Lead Research Organisation:
University of Birmingham
Department Name: School of Physics and Astronomy
Abstract
The study of neutron interactions with matter underpins our understanding of everything from the resilience of materials in a nuclear reactor, the production of radionuclides which are produced inside a reactor with potential for medical applications, all the way to understanding the radiobiology of neutron interactions with cells and the potential for both the formation and treatment of cancer. Unlike understanding the interaction of protons, where high fluxes of protons, or even ions, is possible, creating intense beams of neutrons is extremely challenging. As such the properties of matter irradiated by neutrons is an area which still requires advances in research. This is particularly the case for the understanding of nuclear reactors. Present generation reactors have lifetime limits which are often restricted by the materials performance of either the moderator (for example in the AGR power stations this is graphite), reactor pressure vessel (e.g. in PWR designs) or even the reliability of the systems, both electronic and mechanical, that are used in the control and operation of the reactor. Measurements of the degradation of the properties allow a prediction of their lifetime to failure and hence enhances safety and assurance. However, this is rather an empirical approach and a more sophisticated method would be to develop a detailed understanding of the damage mechanisms and how these then link to the macroscopic materials failure characteristics, such as embrittlement or radiation assisted corrosion. To develop this understanding it is necessary to irradiate materials and then understand how their properties are being transformed on the microscopic scale. This may then be used to motivate the development of accurate models of the processes which may be used to predict materials failure.
The limited availability of neutron irradiation facilities has resulted in the use of proton irradiation to attempt to simulate the almost identical neutron. However, the neutron is different in a very important way - it is uncharged. As a proton passes through a material, as well as colliding with the atomic nuclei, its charge perturbs the electrons. Thus, the type of damage is very different. To move the field forward a well-developed neutron irradiation programme is required. This can be performed in materials test reactors, but these are expensive, have limited access and thus constrain the volume of research that can be performed. The creation of new reactor test facilities is expensive and challenging due to the challenges and expense in their operation. An exciting alternative is to use an accelerator based approach which accelerates protons and, through a nuclear reaction, converts them to neutrons and thus, a flux of neutrons can be created. To do this requires a high current proton accelerator. It is only recently that credible accelerators with the required properties have been developed and exploited.
The present proposal is to use this approach to create an accelerator based neutron irradiation facility at the University of Birmingham. This will be capable of creating neutron fluxes which are close to that inside a nuclear reactor which may be used for materials irradiation. The flexibility of the facility will allow testing of the degradation of materials during the irradiation, i.e. in situ, to better characterise the changes to the material. The intention is to establish a national facility which allows users to develop a scientific programme which links to the higher flux materials test reactors. It will draw in existing facilities such as the MC40 cyclotron at the University of Birmingham, and the precision energy neutron facility at the National Physical Laboratory. This breadth of capability will provide the UK community with a suite of nuclear facilities capable of supporting the development of the nuclear sector.
The limited availability of neutron irradiation facilities has resulted in the use of proton irradiation to attempt to simulate the almost identical neutron. However, the neutron is different in a very important way - it is uncharged. As a proton passes through a material, as well as colliding with the atomic nuclei, its charge perturbs the electrons. Thus, the type of damage is very different. To move the field forward a well-developed neutron irradiation programme is required. This can be performed in materials test reactors, but these are expensive, have limited access and thus constrain the volume of research that can be performed. The creation of new reactor test facilities is expensive and challenging due to the challenges and expense in their operation. An exciting alternative is to use an accelerator based approach which accelerates protons and, through a nuclear reaction, converts them to neutrons and thus, a flux of neutrons can be created. To do this requires a high current proton accelerator. It is only recently that credible accelerators with the required properties have been developed and exploited.
The present proposal is to use this approach to create an accelerator based neutron irradiation facility at the University of Birmingham. This will be capable of creating neutron fluxes which are close to that inside a nuclear reactor which may be used for materials irradiation. The flexibility of the facility will allow testing of the degradation of materials during the irradiation, i.e. in situ, to better characterise the changes to the material. The intention is to establish a national facility which allows users to develop a scientific programme which links to the higher flux materials test reactors. It will draw in existing facilities such as the MC40 cyclotron at the University of Birmingham, and the precision energy neutron facility at the National Physical Laboratory. This breadth of capability will provide the UK community with a suite of nuclear facilities capable of supporting the development of the nuclear sector.
Planned Impact
The main impact of the proposed facilities will be to i) the nuclear industry associated with nuclear the safe operation of nuclear reactors, ii) the nuclear regulator charged with the oversight of the safe operation of the UK nuclear fleet, iii) those charged with maintaining the nuclear waste facilities and the decommissioning of sites, iv) the development of geological waste facilities, v) the creation of next generation of nuclear plants such as Gen IV and fusion, vi) those developing next generation SMR and AMR designs.
The impact will be via the ability to characterise the degradation of materials under irradiation, and hence develop, an enhanced understanding of the lifetime of nuclear plant materials, mitigation strategies and radiation resistant or tolerant materials. Loss of operation of nuclear power plant reactors costs an estimated £1M/day and for a fleet of nuclear reactors the commercial impact is billions of pounds per year. The safe operation of nuclear reactors is of prime interest to the UK public and the ONR. The level of confidence is directly related to the ability to understand the performance and safety of nuclear power plant. The characterisation of nuclear materials is the most critical issue. Future developments in the field of nuclear energy, fission and fusion, rely on having a skilled workforce with a deep understanding of nuclear power technology and the underpinning science. The skills base the facility will create will be of high importance to the development of the sector.
The High Flux Accelerator-Driven Neutron Irradiation Facility for Nuclear Plant Materials and Applied Neutron Science will deliver the above impact by establishing a facility which will i) deliver a fundamental nuclear materials research programme, ii) develop collaborative research between the academic community and the nuclear industry and iii) allow commercial irradiation measurements to be performed by the nuclear industry.
The facility will develop a national training programme that will establish a series of training opportunities related to working with nuclear accelerators, materials irradiation, radioprotection and nuclear safety, nuclear instrumentation and techniques, nuclear data and measurement and dosimetry and metrology. The aim is to boost the UK skills base with high end expertise with direct benefit to the nuclear industry and related sectors such as medical physics and cancer therapy.
The impact will be via the ability to characterise the degradation of materials under irradiation, and hence develop, an enhanced understanding of the lifetime of nuclear plant materials, mitigation strategies and radiation resistant or tolerant materials. Loss of operation of nuclear power plant reactors costs an estimated £1M/day and for a fleet of nuclear reactors the commercial impact is billions of pounds per year. The safe operation of nuclear reactors is of prime interest to the UK public and the ONR. The level of confidence is directly related to the ability to understand the performance and safety of nuclear power plant. The characterisation of nuclear materials is the most critical issue. Future developments in the field of nuclear energy, fission and fusion, rely on having a skilled workforce with a deep understanding of nuclear power technology and the underpinning science. The skills base the facility will create will be of high importance to the development of the sector.
The High Flux Accelerator-Driven Neutron Irradiation Facility for Nuclear Plant Materials and Applied Neutron Science will deliver the above impact by establishing a facility which will i) deliver a fundamental nuclear materials research programme, ii) develop collaborative research between the academic community and the nuclear industry and iii) allow commercial irradiation measurements to be performed by the nuclear industry.
The facility will develop a national training programme that will establish a series of training opportunities related to working with nuclear accelerators, materials irradiation, radioprotection and nuclear safety, nuclear instrumentation and techniques, nuclear data and measurement and dosimetry and metrology. The aim is to boost the UK skills base with high end expertise with direct benefit to the nuclear industry and related sectors such as medical physics and cancer therapy.
Organisations
Publications
Bishop J
(2022)
Neutron-upscattering enhancement of the triple-alpha process.
in Nature communications
Gai M
(2020)
Time Projection Chamber (TPC) detectors for nuclear astrophysics studies with gamma beams
in Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Garg R
(2023)
Ta 179 ( n , ? ) cross-section measurement and the astrophysical origin of the Ta 180 isotope
in Physical Review C
Giomataris I
(2023)
Neutron spectroscopy with a high-pressure nitrogen-filled spherical proportional counter
in Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Turner AN
(2021)
Convolutional Neural Networks for Challenges in Automated Nuclide Identification.
in Sensors (Basel, Switzerland)
Wheldon C
(2022)
Position sensitive detector applications in nuclear physics and nuclear industry
in Journal of Instrumentation
Description | The present award was to develop a accelerator driven neutron facility as a first of its kind worldwide. The facility was to deploy a high intensity proton beam onto a rotating target to produce the world leading accelerator driven neutron facility for neutrons of energy a few hundred keV. The development of the facility pushes many technology barriers, plus the development of robotic radiation handling systems. The facility has now been successfully commissioned and now forms a template for the creation of other such facilities worldwide. These can be used for a range of science from radiobiology to nuclear materials testing and isotope production. |
Exploitation Route | The impact of the research programme of the facility will be in the fields of: - characterisation of neutron irradiation of materials used in nuclear fission and fusion energy - characterisation of effect of neutron interactions with biological materials - nuclear science and data - isotope production, including medical isotopes. |
Sectors | Energy Healthcare |
URL | https://www.birmingham.ac.uk/research/activity/nuclear/about-us/facilities/high-flux-neutron-facility.aspx |
Description | The neutron irradiation facility funded through the National Nuclear User Facility programme began operation in early 2024. The facility is designed to produce fluxes of neutrons close to the intensity that would be found inside a small nuclear reactor. The facility is based around a machine developed by the US based company Neutron Therapeutics, but in the present application is being operated closer to the limits of the capability, this is in terms of intensity of the neutrons created and the duration of production. The learnings from this project are feeding back into the future design of the accelerator by NT and also into the design of other facilities worldwide. The science programme is beginning to take place on the accelerator with early studies on the behaviour of optical fibres, neutron attenuation in shielding materials, irradiation of superconducting materials, isotope production and radiobiology. The findings from these measurements will be important for the fields of control systems, nuclear reactors, fusion reactors, nuclear medicine and nuclear data. The impact will reach from the academia to industry. |
First Year Of Impact | 2024 |
Sector | Energy,Healthcare |
Description | Contribution to Environmental Audit Committee SMR Consultation Response |
Geographic Reach | National |
Policy Influence Type | Contribution to a national consultation/review |
Description | Establishment of Midlands Nuclear |
Geographic Reach | Local/Municipal/Regional |
Policy Influence Type | Contribution to new or improved professional practice |
URL | https://midlandsnuclear.co.uk/ |
Description | Development of an in-situ characterisation facility for both proton and neutron irradiation |
Amount | £1,296,308 (GBP) |
Funding ID | EP/V035649/1 |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 09/2021 |
End | 09/2024 |
Description | Towards nuclear astrophysics measurements at the NEW Birmingham High-Flux Accelerator-Driven Neutron Facility (HF-ADNeF) |
Amount | £191,274 (GBP) |
Funding ID | ST/W006073/1 |
Organisation | Science and Technologies Facilities Council (STFC) |
Sector | Public |
Country | United Kingdom |
Start | 03/2022 |
End | 10/2024 |
Description | CCFE |
Organisation | Culham Centre for Fusion Energy |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Collaborative research |
Collaborator Contribution | Access to facilities at the CCFE Materials Research Facility |
Impact | Collaborative research programmes |
Start Year | 2018 |
Description | NPL |
Organisation | National Physical Laboratory |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Collaborative research |
Collaborator Contribution | Experimental programme developed on the UoB facilities |
Impact | Development of metrology standards and methods |
Start Year | 2015 |
Description | ORNL |
Organisation | Oak Ridge National Laboratory |
Country | United States |
Sector | Public |
PI Contribution | Research collaboration, developing joint experimental programme. |
Collaborator Contribution | Support of PhD students |
Impact | Joint conference |
Start Year | 2021 |
Description | Rolls Royce |
Organisation | Rolls Royce Group Plc |
Department | Rolls-Royce Civil Nuclear |
Country | United Kingdom |
Sector | Private |
PI Contribution | Collaborative research on nuclear materials |
Collaborator Contribution | Expertise and motivation from the nuclear reactor design |
Impact | Experimental research programme |
Start Year | 2012 |
Description | UHB |
Organisation | University Hospitals Birmingham NHS Foundation Trust |
Country | United Kingdom |
Sector | Public |
PI Contribution | Access to facilities for collaborative research related to BNCT |
Collaborator Contribution | Collaborative research related to BNCT |
Impact | Many papers, but the present facility supported by this grant is under construction. |
Description | NAILS |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Industry/Business |
Results and Impact | Presentation to the nuclear industry group NAILS |
Year(s) Of Engagement Activity | 2019 |
Description | Presentation to NuPECC |
Form Of Engagement Activity | A formal working group, expert panel or dialogue |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | Presentation of UoB capabilities to the NuPECC group (European body for Nuclear Physics and Nuclear Science) |
Year(s) Of Engagement Activity | 2021 |
Description | Presentation to Nuclear Physics Community Meeting |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Professional Practitioners |
Results and Impact | Nuclear Physics meeting with academics, industry and research council participants. The 2 day event was to update the community on new and ongoing projects |
Year(s) Of Engagement Activity | 2024 |
Description | Surrey |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Professional Practitioners |
Results and Impact | Seminar at the University of Surrey |
Year(s) Of Engagement Activity | 2019 |
Description | Workshop 2020 |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | This was a workshop to develop a community around the new facility which is under construction |
Year(s) Of Engagement Activity | 2020 |