Summary
The INTER project aims at the design and production of a proof of concept demonstrator component essential for the development of a novel, tunable and portable neutron source.
Neutron beam-based analysis (neutron diffraction, neutron activation analysis, active interrogation) and imaging (radiography, tomography) methods are a powerful tool for non-destructive testing (NDT) of materials and find numerous important applications in industry, security, and material science and technology.
Use of laser-driven ion accelerators to generate neutrons can potentially overcome the limitations of conventional neutrons sources.
Within the ERC-CoG ENSURE project, I developed a nanostructured material, used to produce a novel multi-layer target concept] allowing to enhance the laser-ion production efficiency with reduced laser requirements and, at the same time, robust enough to be adopted in a commercial targetry device, paving the way for operation with relatively low-energy, commercial, high rep-rate laser systems (1J; 1-10TW; 10-100 Hz).
Upon approval of the present INTER ERC-PoC project, I will provide an accelerator module demonstrator, based on such novel target concept, for the generation of an innovative, portable neutron source.
If successful, INTER will open the way to put on the market a ready-to-use compact accelerator module able to generate ion & neutron beams with a transportable, affordable laser system. Availability of this technology would find important applications of strong economical and societal interest, like checking for drugs and explosives concealed in luggage and cargo containers, in-situ analysis of key industrial (e.g. engine turbines blades) and electronic (e.g. to measure impurities in silicon semiconductors) components, imaging/interrogation of nuclear fuels, explosives, cultural heritage artifacts, as well as in biology, medicine, fuel cell research and geoscience.
Neutron beam-based analysis (neutron diffraction, neutron activation analysis, active interrogation) and imaging (radiography, tomography) methods are a powerful tool for non-destructive testing (NDT) of materials and find numerous important applications in industry, security, and material science and technology.
Use of laser-driven ion accelerators to generate neutrons can potentially overcome the limitations of conventional neutrons sources.
Within the ERC-CoG ENSURE project, I developed a nanostructured material, used to produce a novel multi-layer target concept] allowing to enhance the laser-ion production efficiency with reduced laser requirements and, at the same time, robust enough to be adopted in a commercial targetry device, paving the way for operation with relatively low-energy, commercial, high rep-rate laser systems (1J; 1-10TW; 10-100 Hz).
Upon approval of the present INTER ERC-PoC project, I will provide an accelerator module demonstrator, based on such novel target concept, for the generation of an innovative, portable neutron source.
If successful, INTER will open the way to put on the market a ready-to-use compact accelerator module able to generate ion & neutron beams with a transportable, affordable laser system. Availability of this technology would find important applications of strong economical and societal interest, like checking for drugs and explosives concealed in luggage and cargo containers, in-situ analysis of key industrial (e.g. engine turbines blades) and electronic (e.g. to measure impurities in silicon semiconductors) components, imaging/interrogation of nuclear fuels, explosives, cultural heritage artifacts, as well as in biology, medicine, fuel cell research and geoscience.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/754916 |
| Start date: | 01-05-2017 |
| End date: | 31-10-2018 |
| Total budget - Public funding: | 149 375,00 Euro - 149 375,00 Euro |
Cordis data
Original description
The INTER project aims at the design and production of a proof of concept demonstrator component essential for the development of a novel, tunable and portable neutron source.Neutron beam-based analysis (neutron diffraction, neutron activation analysis, active interrogation) and imaging (radiography, tomography) methods are a powerful tool for non-destructive testing (NDT) of materials and find numerous important applications in industry, security, and material science and technology.
Use of laser-driven ion accelerators to generate neutrons can potentially overcome the limitations of conventional neutrons sources.
Within the ERC-CoG ENSURE project, I developed a nanostructured material, used to produce a novel multi-layer target concept] allowing to enhance the laser-ion production efficiency with reduced laser requirements and, at the same time, robust enough to be adopted in a commercial targetry device, paving the way for operation with relatively low-energy, commercial, high rep-rate laser systems (1J; 1-10TW; 10-100 Hz).
Upon approval of the present INTER ERC-PoC project, I will provide an accelerator module demonstrator, based on such novel target concept, for the generation of an innovative, portable neutron source.
If successful, INTER will open the way to put on the market a ready-to-use compact accelerator module able to generate ion & neutron beams with a transportable, affordable laser system. Availability of this technology would find important applications of strong economical and societal interest, like checking for drugs and explosives concealed in luggage and cargo containers, in-situ analysis of key industrial (e.g. engine turbines blades) and electronic (e.g. to measure impurities in silicon semiconductors) components, imaging/interrogation of nuclear fuels, explosives, cultural heritage artifacts, as well as in biology, medicine, fuel cell research and geoscience.
Status
CLOSEDCall topic
ERC-PoC-2016Update Date
27-04-2024
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