HETEROSTRUCTURE RADIATION DETECTOR MATERIALS FOR ADVANCED TIME OF FLIGHT POSITRON EMISSION TOMOGRAPHY (TOF-PET) IMAGING
Lead Research Organisation:
CRANFIELD UNIVERSITY
Department Name: Sch of Aerospace, Transport & Manufact
Abstract
This proposal aims at developing advanced radiation detector materials for Time of Flight Positron Emission Tomography (ToF-PET) imaging by exploiting the novel concept of high performance multi-material radiation sensing heterostructures. These heterostructures will contribute to the development of next generation imaging technologies for diagnostic, monitoring and therapeutic applications, specifically, by substantially improving the capabilities of ToF-PET technology. These heterostructures will enable i) enhanced diagnostic power; ii) reduced risk to patients (dose efficiency); iii) increased procedural flexibility (i.e. planning of radiation dose strategies and reduced examination time); and eventually iv) direct ToF-PET imaging by rendering the currently time-consuming post-acquisition reconstruction stage obsolete. This effort will be supported by multi-disciplinary facilitation of the design, fabrication and characterisation of the heterostructures, in order to develop an advanced detector material solution for use in current and future ToF-PET detector modules. The output and impact of the research will be maximised through functional testing of the proposed heterostructure detector module. The proposal matches the aspirations of the EPSRC's Healthcare Technologies research theme by i) optimising treatment and care through effective diagnosis, patient-specific prediction and evidence-based intervention; ii) supporting the development of technologies to enhance efficacy, minimise costs and reduce risk to patients; and iii) bringing together a multidisciplinary team with expertise in material science, precision engineering and instrumentation, who will be further supported by external advisors, ToF-PET experts and industrial partners for providing guidance and ensuring the transformational impact of the proposed effort.
Planned Impact
The resulting heterostructure, having multiple materials working in synergy, will have the potential to maintain a short attenuation length comparable to LSO while providing a usable part of its signal within a sub-nanosecond time range, a fundamental criterion for improving the CRT of ToF-PET scanners. Quantitatively, the proposal targets a decrease of the CRT down to about 50 or less ps full width half maximum (FWHM). This improvement will have tremendous implications for the ToF-PET capabilities and will initiate a virtuous circle with benefits involving, but not restricted to, the improvement of the diagnostic power (c.f. Fig. 2); reduction of the examination time; increase of the effective dose sensitivity by a factor of about 10 (i.e. [25]). This will result in a decrease of the required injected dose of 1 order of magnitude with a Whole-Body PET/CT dose of about 1 mSv. This will provide much needed flexibility in treatment planning (e.g. either by using PET as a less-invasive technique for a similar image quality or by enhancing the diagnostic power for a similar injected dose), and it will also enable improved and/or new modalities: e.g. i) use of PET imaging as pre- and post-natal diagnostic tool for detecting neuro-chemical abnormalities associated with neurologic disorders as well as to study normal brain development; ii) advancement of image-guided radiation therapy (e.g. improved disease extent appraisal, and assessment of therapy response); iii) better-earlier prediction of outcome or tumour recurrence; iv) selected screening applications, such as a secondary screen for lung cancer after obtaining suggestive low-dose CT results; v) distribution of radiotracers becomes more cost-effective if lower injected activities can still yield high-quality images. It may even be possible to distribute tracers based on shorter-lived radionuclides, particularly 11C; vi) multiple radiotracers imaging and eventually vii) direct ToF imaging. Finally this project is highly complementary to the current efforts to develop a first-generation total-body PET/CT scanners
Organisations
- CRANFIELD UNIVERSITY (Lead Research Organisation)
- LOUGHBOROUGH UNIVERSITY (Collaboration)
- Czech Technical University in Prague (Collaboration)
- European Organization for Nuclear Research (CERN) (Collaboration)
- University of Tartu (Collaboration)
- QUEEN MARY UNIVERSITY OF LONDON (Collaboration)
- University of Ancona (Collaboration)
- FH Aachen (Collaboration)
- University of Ghent (Collaboration)
- CRANFIELD UNIVERSITY (Collaboration)
- Kurchatov Institute (Collaboration)
- UNIVERSITY OF LEEDS (Collaboration)
- Technion - Israel Institute of Technology (Collaboration)
- University of Milano-Bicocca (Collaboration)
- Lawrence Berkeley National Laboratory (Collaboration, Project Partner)
- University of Kharkiv (Collaboration)
- Academy of Sciences of the Czech Republic (Collaboration)
- Claude Bernard University Lyon 1 (UCBL) (Collaboration)
- KING'S COLLEGE LONDON (Collaboration)
- Saint Gobain Crystals (Project Partner)
- University of Lincoln (Project Partner)
- European Organization for Nuclear Research (Project Partner)
- Science and Technology Facilities Council (Project Partner)
- University of California, Berkeley (Project Partner)
- General Electric (United States) (Project Partner)
- King's College London (Project Partner)
Publications
Hawi S
(2022)
Critical Review of Nanopillar-Based Mechanobactericidal Systems
in ACS Applied Nano Materials
Chen WL
(2022)
Clay Swelling: Role of Cations in Stabilizing/Destabilizing Mechanisms.
in ACS omega
Ye W
(2022)
Enhancing Large-Area Scintillator Detection with Photonic Crystal Cavities
in ACS Photonics
Faisal N
(2022)
Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges
in Advanced Engineering Materials
Krause P
(2023)
Advances in Design of High-Performance Heterostructured Scintillators for Time-of-Flight Positron Emission Tomography
in Advanced Theory and Simulations
Rogers E
(2023)
Two-dimensional perovskite functionalized fiber-type heterostructured scintillators
in Applied Physics Letters
LarraƱaga-Altuna M
(2021)
Bactericidal surfaces: An emerging 21st-century ultra-precision manufacturing and materials puzzle
in Applied Physics Reviews
Fan P
(2021)
Origins of ductile plasticity in a polycrystalline gallium arsenide during scratching: MD simulation study
in Applied Surface Science
Kumar Mishra R
(2021)
Computational prediction of electrical and thermal properties of graphene and BaTiO3 reinforced epoxy nanocomposites
in Biomaterials and Polymers Horizon
Fazeli Jadidi M
(2020)
Distribution of shallow NV centers in diamond revealed by photoluminescence spectroscopy and nanomachining
in Carbon
Yin J
(2021)
An analytical model to predict the depth of sub-surface damage for grinding of brittle materials
in CIRP Journal of Manufacturing Science and Technology
Fan P
(2021)
An atomistic investigation on the wear of diamond during atomic force microscope tip-based nanomachining of gallium arsenide
in Computational Materials Science
Viswanathan V
(2021)
Role of thermal spray in combating climate change
in Emergent Materials
Faisal N
(2021)
Large-scale manufacturing route to metamaterial coatings using thermal spray techniques and their response to solar radiation
in Emergent Materials
Katiyar N
(2021)
Emergence of machine learning in the development of high entropy alloy and their prospects in advanced engineering applications
in Emergent Materials
Shishkin A
(2021)
Using circular economy principles to recycle materials in guiding the design of a wet scrubber-reactor for indoor air disinfection from coronavirus and other pathogens.
in Environmental technology & innovation
Krause P
(2022)
Design rules for time of flight Positron Emission Tomography (ToF-PET) heterostructure radiation detectors.
in Heliyon
Khatri N
(2020)
Surface defects incorporated diamond machining of silicon
in International Journal of Extreme Manufacturing
Wang Y
(2021)
Fabrication of three-dimensional sin-shaped ripples using a multi-tip diamond tool based on the force modulation approach
in Journal of Manufacturing Processes
Mir A
(2022)
Challenges and issues in continuum modelling of tribology, wear, cutting and other processes involving high-strain rate plastic deformation of metals.
in Journal of the mechanical behavior of biomedical materials
Popov V
(2022)
Industry 4.0 and Digitalisation in Healthcare
in Materials
Fan P
(2021)
Molecular dynamics simulation of AFM tip-based hot scratching of nanocrystalline GaAs
in Materials Science in Semiconductor Processing
Goel S
(2020)
Horizons of modern molecular dynamics simulation in digitalized solid freeform fabrication with advanced materials
in Materials Today Chemistry
Goel S
(2020)
Resilient and agile engineering solutions to address societal challenges such as coronavirus pandemic.
in Materials today. Chemistry
Title | Data for the paper "Horizons of modern molecular dynamics simulation in digitalised solid freeform fabrication with advanced materials" |
Description | Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_Horizons_of_modern_molecular_dynamic... |
Title | Data for the paper "Horizons of modern molecular dynamics simulation in digitalised solid freeform fabrication with advanced materials" |
Description | Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_Horizons_of_modern_molecular_dynamic... |
Title | Data for the paper "Horizons of modern molecular dynamics simulation in digitalised solid freeform fabrication with advanced materials" |
Description | Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_Horizons_of_modern_molecular_dynamic... |
Title | Data for the paper "Horizons of modern molecular dynamics simulation in digitalised solid freeform fabrication with advanced materials" |
Description | Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_Horizons_of_modern_molecular_dynamic... |
Title | Data for the paper "In-depth microscopic characterisation of the weld faying interface revealing stress-induced metallurgical transformations during friction stir spot welding" |
Description | This is the data for the paper to be submitted to an Int Journal of Machine Tools and Manufacture |
Type Of Art | Image |
Year Produced | 2021 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_In-depth_microscopic_characterisatio... |
Title | Data for the paper "In-depth microscopic characterisation of the weld faying interface revealing stress-induced metallurgical transformations during friction stir spot welding" |
Description | This is the data for the paper to be submitted to an Int Journal of Machine Tools and Manufacture |
Type Of Art | Image |
Year Produced | 2021 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_In-depth_microscopic_characterisatio... |
Title | Data for the paper "New insights into the methods for predicting ground surface roughness in the age of digitalisation" |
Description | Research Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_New_insights_into_the_methods_for_pr... |
Title | Data for the paper "New insights into the methods for predicting ground surface roughness in the age of digitalisation" |
Description | Research Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_New_insights_into_the_methods_for_pr... |
Title | Data for the paper "New insights into the methods for predicting ground surface roughness in the age of digitalisation" |
Description | Research Data |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Data_for_the_paper_New_insights_into_the_methods_for_pr... |
Title | Nature inspired materials: Emerging trends and future prospects |
Description | Nature inspired materials images |
Type Of Art | Image |
Year Produced | 2020 |
URL | https://cord.cranfield.ac.uk/articles/figure/Nature_inspired_materials_Emerging_trends_and_future_pr... |
Description | Overall, successful development of fibre based heterostructured scintillator pixels (prototypes). More specifically, the main scientific achievements are articulated around three primary and scientifically interconnected areas that have contributed to the development of heterostructured detector materials: ā¢ The award has set out the first physics-based framework towards the design and performance optimization of the heterostructured scintillators. Whilst heterostructured scintillators have attracted recent interest, they were impeded by the large parameter space that must be navigated to achieve real gain and optimum performance. A multifunctional heterostructure requires the down selection of at least two scintillators in terms of materials composition, type, and performance but also their compatibility and synergetic assembly. This large compositional and geometrical space had challenged and slowed down their development. Specifically, the project has permitted to move from a predominantly time-consuming Edisonian to a scientifically guided approach. The latter has allowed to identify the detector designs that can compete with the current ToF-PET detector standards, but more importantly has shown the ones that can drastically supersede the current technology. ā¢ The award has designed, developed and optimised cost-effective precision-engineering processes for the development and assembly of the different heterostructured scintillator components. Specifically, this encompasses the development and implementation of 1) precision milling procedures for high quality texturing of hard and brittle single crystals; 2) surface functionalisation for assembly compatibility of the different detector components as well as for improved light management; and 3) assembly and post-processing procedures (e.g., precision polishing) for pixel assembly. ā¢ The award has manufactured and tested the first fibre-based prototypes of heterostructured scintillators with 1) high sharing energy capability (design from first item hereabove, implementation from second item hereabove); 2) three different fast emitting components (fast emitting polymer, nanocomposite and perovskite); and 3) improved scintillation performance compared to standard monolithic scintillators, but more importantly improved Coincidence Timing Resolution, the main performance marker directly related to the performance of ToF-PET scanners. These outcomes, while they need further validation for an industry transfer, have demonstrated the possibility and viability of the entire heterostructure approach, including directly quantification of its benefit. |
Exploitation Route | While the outcomes need further validation to be fully adopted by industry, the successful development of a heterostructure scintillator pixels prototype for Time-of-Flight Positron Emission Tomography has already triggered numerous interested across the medical imaging community (end user, instrumentation and crystal producer companies). Several discussions on how to optimize the performance of the heterostructure and how to scale-up the production have been initiated. Similarly, the projects has open some pathways toward other sectors of activities such as the development of advances optical coating for the energy sector (activity related to the light management of the award) and the development of novel type of radiation sensing for the nuclear sector (activity related to the precision engineering of single crystal of the award). |
Sectors | Energy,Healthcare,Manufacturing, including Industrial Biotechology |
Description | COVID-19 Grant Extension Allocation |
Amount | Ā£115,300 (GBP) |
Organisation | United Kingdom Research and Innovation |
Sector | Public |
Country | United Kingdom |
Start | 04/2021 |
End | 09/2021 |
Description | PhD studentship - EPSRC - Centre for Doctoral Training in Ultra Precision Engineering |
Amount | Ā£44,331 (GBP) |
Organisation | Engineering and Physical Sciences Research Council (EPSRC) |
Sector | Public |
Country | United Kingdom |
Start | 01/2019 |
End | 01/2022 |
Description | Studentship - PhD |
Amount | Ā£45,000 (GBP) |
Organisation | University Ferhat Abbas of Setif |
Sector | Academic/University |
Country | Algeria |
Start | 02/2022 |
End | 03/2025 |
Title | Bactericidal Surfaces: An Emerging 21st Century Ultra-Precision Manufacturing and Materials Puzzle |
Description | Figures |
Type Of Material | Database/Collection of data |
Year Produced | 2020 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Bactericidal_Surfaces_An_Emerging_21st_Century_Ultra-P... |
Title | Data for the paper titled "Using circular economy principles to recycle materials in guiding the design of a wet scrubber-reactor for indoor air disinfection from coronavirus and other pathogens" |
Description | Data for the two graphs is provided as the raw data! |
Type Of Material | Database/Collection of data |
Year Produced | 2021 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Data_for_the_paper_titled_Using_circular_economy_princ... |
Title | Data supporting the publication 'Clay swelling: role of cations in stabilizing/destabilizing mechanisms' |
Description | In the compressed dataset, there are two subdirectories, one in the name of 'Example' and another 'PostprocessData'. The Example directory contains input files, output data and postprocessed data for case Na12 starting at a d-space of onelayer value, where files starts with in.* are input files for lammps software, files ending with .dat or .lmptrj are output files from lammps, and files ending with .mat are matlab processed data. The 'postporcessedata' contains matlab processed results for all simulations in this study, contains simulation for NaMMT, KMMT, CaMMT and NaBD starting at onelayer, twolayer and threelayer d-space values. |
Type Of Material | Database/Collection of data |
Year Produced | 2022 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Data_supporting_the_publication_Clay_swelling_role_of_... |
Title | Thermal response of multi-layer UV crosslinked PEGDA hydrogels |
Description | All data sets are raw data from thermoresponse behaviour of hydrogels. 1. Swelling test for multi-150 um hydrogels with 1.8 mg/ml of photoabsorber.2. Swelling test for mono-5 mm hydrogels with 0 mg/ml of photoabsorber.3. Swelling test for multi-20 um hydrogels with 9 mg/ml of photoabsorber.4. Swelling test for mono-3 mm and mono-1.5 mm hydrogels with 0 mg/ml of photoabsorber.5. Cyclic test for multi-150 um hydrogels.6. Dried weight and solid residue weight of all hydrogels samples7. EWC, NWF, NVF-summary for all hydrogel samples8. DSC-TG-Thermogram-All sample types |
Type Of Material | Database/Collection of data |
Year Produced | 2022 |
Provided To Others? | Yes |
URL | https://cord.cranfield.ac.uk/articles/dataset/Thermal_response_of_multi-layer_UV_crosslinked_PEGDA_h... |
Description | Advanced characterization of heterostructured scintillators - X-ray imaging |
Organisation | Claude Bernard University Lyon 1 (UCBL) |
Country | France |
Sector | Academic/University |
PI Contribution | Development of heterostructured scintillator pixels. |
Collaborator Contribution | Characterization of the heterostructured scintillator by x-ray imaging |
Impact | The advanced x-ray imaging has provided new insight in terms of inner structure and light propagation capability of the single crystal matrix developed at Cranfield. This has fed back to the optimization of the precision engineering process of milling/drilling the single crystal matrix. |
Start Year | 2021 |
Description | Metal Organic Framework (MOF) as ultra fast emitter for heterostructured scintillators |
Organisation | University of Milano-Bicocca |
Country | Italy |
Sector | Academic/University |
PI Contribution | Design, manufacturing of single crystal matrix to act as vessel for heterostructured detectors |
Collaborator Contribution | MOF synthesis and characterization. Functionalization of the single crystal matrix |
Impact | Novel approach to heterostructured scintillator functionalization It is a multidisciplinary collaboration merging the chemistry of MOF to the precision engineering and detector physics |
Start Year | 2021 |
Description | Nanocomposite as ultra fast and dense emitter for heterostructured scintillators |
Organisation | University of Ghent |
Country | Belgium |
Sector | Academic/University |
PI Contribution | Gent University is specialized in synthesis and optimization of optical nanoparticle. The custom nanoparticle called nano platelet have been used as loading component of a polymer to enhanced its emission (sub nanosecond) and the overall density of the polymer. The loaded polymer was then implemented in single crystal matrix to finalize the heterostructured detector. The loading, polymer and single crystal matrix were all designed, developed and tested at Cranfield University. |
Collaborator Contribution | Gent has been developing some specific nanoparticle to act as ultra fast and dense emitter in the heterostructured scintillators. The nanoparticle are specifically synthesized for Cranfield. Gent has also participated in the support of the loading both experimentally and by guiding the development through quarterly meetings. |
Impact | Assessment of the scalability of nanoparticle Custom and improved performance ultra fast emitter It is a multidisciplinary collaboration merging the chemistry of nanoparticle to the precision engineering and detector physics |
Start Year | 2022 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Academy of Sciences of the Czech Republic |
Country | Czech Republic |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Claude Bernard University Lyon 1 (UCBL) |
Country | France |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Cranfield University |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Czech Technical University in Prague |
Country | Czech Republic |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | European Organization for Nuclear Research (CERN) |
Country | Switzerland |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | FH Aachen |
Country | Germany |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | King's College London |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Kurchatov Institute |
Country | Russian Federation |
Sector | Public |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Lawrence Berkeley National Laboratory |
Country | United States |
Sector | Public |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | Technion - Israel Institute of Technology |
Country | Israel |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | University of Ancona |
Country | Italy |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | University of Ghent |
Country | Belgium |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | University of Kharkiv |
Country | Ukraine |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | University of Leeds |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | University of Milano-Bicocca |
Country | Italy |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | New Crystal Clear Collaboration collaboration: development of heterostructure scintillator |
Organisation | University of Tartu |
Country | Estonia |
Sector | Academic/University |
PI Contribution | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. Cranfield is involved in mulltiple work packages in direct relation with the development of heretostructure scintillator materials. - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: Cranfield - Simulation and heterostructure pixel design: Cranfield - Developement of microstructure: Cranfield - Realization of heterostructure pixels: Cranfield - Characterization of heterostructure pixel: Cranfield, |
Collaborator Contribution | - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Technion - Developement of microstructure: CERN, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. |
Impact | This collaboration will allow a concerted effort and a multidisciplinary approach to the development of heterostructure detector materials both scientifically and commercially. The agreement will allow sample exchange and access to each institution facility. The collaboration will meet to evaluate the progress and devise the best research pathways to success. |
Start Year | 2019 |
Description | Perovskite fibre for heterostructured scintillators |
Organisation | Queen Mary University of London |
Department | School of Engineering and Materials Science |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | The collaboration leverage the outputs of two epsrc funded projects (EP/V050311/1 and EP/S013652/1) toward the novel design of heterostructured scintillators. |
Collaborator Contribution | The core of the detector, structured single crystal matrix, has been developed at Cranfield University and the filler, second component based on single crystal perovskite fibres, has been developed at Queen Mary, University of London. |
Impact | Both projects benefit from the collaboration with a new application field for the perovskite fibre and a higher performance filler for the heterostructured detectors. It is a multidisciplinary collaboration merging the chemistry of single crystal growth to the precision engineering and detector physics |
Start Year | 2022 |
Description | Zero reflectivity coating |
Organisation | Loughborough University |
Department | Department of Physics |
Country | United Kingdom |
Sector | Academic/University |
PI Contribution | This an early stage in the collaboration, though Cranfield will bring its knowledge in terms of advanced coatings manufacturing and facilities. |
Collaborator Contribution | Loughborough will bring the physics associated with ultra thin films and optical materials. |
Impact | It is too early to mention outcomes, but the collaboration leverages the strengths of both institutions toward a possible novel approach to optical coatings. This would have tremendous impacts for the detection fields but also for sectors of activities such as energy (photo-voltaic) and defense. This collaboration merges the advanced thin film manufacturing, physics, material sciences and optics. |
Start Year | 2022 |
Description | Invitated speaker to the 16th International Conference on Scintillating Materials & their Applications (SCINT) |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Other audiences |
Results and Impact | Invited talk at the 16th International Conference on Scintillating Materials & their Applications (SCINT) on the precision machining and assembly of heterostructured detectors. The conference was held from September 19 to September 23, 2022 at Santa Fe - USA. |
Year(s) Of Engagement Activity | 2022 |
URL | https://web.cvent.com/event/b707dc85-ddc6-4a0d-89dd-c1ef679ed3ce/summary |
Description | Invitation as key presenter to the 5th edition of the International Conference of Optics (ICO2022) |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Other audiences |
Results and Impact | Presentation the work on heterostructured detectors to a new audience focusing on the optical and precision manufacturing of the scintillators. |
Year(s) Of Engagement Activity | 2022 |
URL | https://ocs.univ-setif.dz/ICO2022/ICO2022 |
Description | Invitation as key speaker to the 16th International Conference on Scintillating Materials & their Applications (SCINT) |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Other audiences |
Results and Impact | Invitation to give a key note on the development and future of heterostructured detector at 16th International Conference on Scintillating Materials & their Applications (SCINT). The conference was held from September 19 to September 23, 2022 at Santa Fe - USA |
Year(s) Of Engagement Activity | 2022 |
URL | https://web.cvent.com/event/b707dc85-ddc6-4a0d-89dd-c1ef679ed3ce/summary |
Description | Invitation to present at Loughborough University, Landau seminars |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Other audiences |
Results and Impact | Invitation by the Physics department of Loughborough University to give a seminar at one of their "Landau seminars" in Spring 2022. |
Year(s) Of Engagement Activity | 2022 |
URL | https://www.lboro.ac.uk/departments/physics/events/seminars/landau-seminars/landauseminars2022/landa... |
Description | Medami 2019 |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | Workshop was attended to present our material development driven project to an audience highly specialized in medical imaging (academics, end users and companies) but not directly involved in the material development. The entire project, goal, challenges and output, was presented. The project, recognized as one of the only way to reach 10ps time resolution of the ToF-PET, has definitely triggered some interest from both end users and companies. Further discussions and plans were made to define how to better support the development of ultra-fast heterostructure detector for ToF-PET and eventually transition the technology from laboratory to industry. |
Year(s) Of Engagement Activity | 2019 |
URL | https://www.i3m.upv.es/medami2019/ |
Description | New Crystal Clear Collaboration project: development of heterostructure scintillator |
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 | Set-up of a formal Crystal Clear Collaboration Collaboration project on the development of heterostructure scintillators as a basis for scintillator based detectors with a time resolution towards 10ps in the frame of the 10ps challenge. This includes 17 institutes of which 11 are CCC members and 6 non-CCC members : 11 CCC members institutes : CERN, Switzerland (Etiennette Auffray); CTU, Prague , Czeck Republic (V. Cuba); Kurchatov institute, Moscow, Russia (G. Dosovitskiy); ILM, Lyon, France (Christophe Dujardin); FZU, Prague Czech republic (M. Nikl); Tartu university, Estonia (Sergey Omelkov); University of Anconna, Italy (D. Rinaldi); ISMA Kharkov, Ukraine, (Oleg Sidelsky); University of leeds, UK (Harry Tsoumpas) ; Lomonosov Institute, Moscow, Russia (Andrei Vasilev); FH Aachen, Germany (Karl Ziemons) Six non- CCC members institutes : University Cranfield, UK (Greg Bizarri); LBL, Berkeley, US (Edith Bourret-Courchesne); Technion University (Ido Kaminer); Ghent University, Belgium (Iwan Moreel); UniMIB, Milano, Italy (Anna Vedda), King's College London, UK (Harris Makatsoris); A first list of activities in which each institute contribute has been establish: - Theoretical understanding of excitation in nanomaterial: Lomonosov institute - Nanomaterial chemistry understanding and synthesis: ILM, CTU, Ghent, FZU, Technion, UNIMIB, Cranfield, King's College London - Optical properties characterization of nanomaterials (time spectroscopy): CERN, CTU, FZU, ILM, LBL, Lomonosov (with Celia institute in Bordeaux), Tartu, Technion - Simulation and heterostructure pixel design: CERN, Cranfield, Technion - Developement of microstructure: CERN, Cranfield, Kurchatov, ISMA - Realization of heterostructure pixels: CERN, Cranfield, ISMA - Characterization of heterostructure pixel: Aachen, Anconna, CERN, Cranfield, - Coincidence time resolution performance: CERN - Image reconstruction: CERN, Uni Leeds. This collaboration will allow a concerted effort and a multidisciplinary approach to efficiently enable the future of heterostructure material detectors both scientifically and commercially. |
Year(s) Of Engagement Activity | 2019 |
URL | https://crystalclear.web.cern.ch/crystalclear/ |
Description | Organisation of the 1st workshop Workshop on scintillator metastructures |
Form Of Engagement Activity | Participation in an activity, workshop or similar |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | The workshop, co-organized by CERN (P. Lecoq) and the Cranfield University (G. Bizarri) has been held at CERN, on Nov 12-13 2019. More than 40 scientists from 15 different countries have participate and presentated their work in direct relation with the future of heterostructure detector material development. The workshop was designed to primaraly focus on the development of ultra-fast heterostructure mmaterials for Time of Flight Positron Emission Tomography (ToF-PET). As stated in the advertisement of the workshop: """In the context of the 10ps Time-of-Flight Positron Emission Tomography (TOFPET) challenge (https://the10ps-challenge.org/), a new class of scintillators needs to be developed. combining the high stopping power and photoelectric cross section of standard scintillators, such as BGO and LSO with the ultrafast scintillation properties of high donor band semi-conductors or quantum confined (multi)-excitonic emission of nanocrystals. The development of such high performance multi-material radiation sensing heterostructures has recently received some further support with the first demonstration/measurement of the energy sharing mechanism projected from the absorption of a 511keV gamma ray in such heterostructures. This is an important step stone. To extend this effort toward the development of more commercially relevant heterostructure PET pixels, we now believe that the establishment of an intersectoral/multidisciplinary community helping to regroup our efforts, define a common strategy, and seek for funding is crucial. Toward these aims and along this very promising line of research, we would like to discuss during a 2 days' workshop three primary and scientifically interconnected areas: · Heterostructure Design - Simulations and optimization · Fast component Development - Performance and technical requirements (density, light yield, scintillation kinetics, transparency, possibility to embed in a host (polymer), production methods and scalability, etc) · Heterostructure Assembly - Integration of the two scintillator components, with a particular focus on the light collection and performance optimization"""" The workshop has served to survey the current state of art in the field of heterostructure radiation detectors, devise the most promising avenues to explore and initiate the appropriate collaboration across the institutions. There will be a follow up workshop to assess the progress in 2020 and 2021. |
Year(s) Of Engagement Activity | 2019 |
Description | Pakistan/UK workshop |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Other audiences |
Results and Impact | Organization and attendance to a face to face and online workshop on research and collaboration activities between Cranfield University and in several Pakistani Universities (e.g., National University of Sciences & Technology - NUST, Islamabad, DHA Suffa University) |
Year(s) Of Engagement Activity | 2022 |
Description | Quantum Dot Day 2020 |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | National |
Primary Audience | Professional Practitioners |
Results and Impact | Presentation given on the development and optimization of ultra-fast nanoparticle loaded polymers for Time of Flight Positron Emission Tomography scanners. The main goal was to present and discuss our results with a highly skill audience of physicists and chemists not directly involved with the medical sector. This aimed to provide a different view on our specific scientific challenges. Discussions were fruitful providing interesting path forward that will be further evaluated in laboratories. |
Year(s) Of Engagement Activity | 2020 |
URL | http://qdd2020.iopconfs.org/home |
Description | SCINT2019 |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | International |
Primary Audience | Professional Practitioners |
Results and Impact | Presentation was given to an audience highly specialized in the development of scintillator materials. The intent was to discuss the scientific challenges related to heterostructure material development and the complex energy transfer mechanisms that are directly associated with it. The presentation of our preliminary results was extremely well received and further discussions were started on how to optimize and scale-up the production of the heterostructures. |
Year(s) Of Engagement Activity | 2019 |
URL | http://www.scint2019.imr.tohoku.ac.jp/ |
Description | Soapbox Science MK 2020 |
Form Of Engagement Activity | A talk or presentation |
Part Of Official Scheme? | No |
Geographic Reach | Regional |
Primary Audience | Public/other audiences |
Results and Impact | Soapbox Science is a novel public outreach platform for promoting women scientists and the science they do. Dr. Edith Rogers presented to a general audience (50-100) the overview of the project and its potential breakthrough in term of medical imaging. The intended output was to engage with a non-specialized audience and for public learning and scientific debate. The presentation was followed by questions from the audience spanning the research challenging (precision engineering, material science) but also the application space (medical, imaging). |
Year(s) Of Engagement Activity | 2020 |
URL | https://mksoapboxscience.wordpress.com/ |