ECCS-EPSRC: A new generation of cost-effective, scalable and stable radiation detectors with ultrahigh detectivity
Lead Research Organisation:
University of Oxford
Department Name: Oxford Chemistry
Abstract
Significantly improved performance of radiation detectors has recently been achieved with lead-halide perovskite single crystals. However, the high lead (Pb) content exceeds the maximum limit set in many jurisdictions (including in the US and UK), and the facile ionic conductivity in these materials limits the range of electric fields that can be applied, thus limiting their operational stability. This proposal will address the challenges of current X-ray detectors, including the use of toxic elements, limited performance, high manufacturing costs, and limited charge-carrier transport. Our preliminary results have shown that BiOI can be the ideal non-toxic alternative to the Pb-based perovskites for next generation radiation detectors because of its high sensitivity and the ability to detect ultralow does rates of X-rays, which arise from its composition of heavy elements, large mobility-lifetime products, and high resistivities. To transfer this technology to industry and to have an impact on medical imaging and nuclear security, we will further 1) improve the mobility-lifetime product to well above 6 +/- 2 x 10^-2 cm2 V-1 s-1 through compositional engineering, 2) increase the size of the detectors by an order of magnitude (from 5 mm currently) without compromising on performance, and 3) optimize the device architecture and imaging performance. The overall aim of this joint research between US team (University at Buffalo) and the UK team (University of Oxford and University of Cambridge) is to develop a new generation of cost-effective, stable and up-scaled bismuth-based radiation detectors capable of detecting three orders of magnitude lower dose rates than the current commercial standard.
Publications
Silva N
(2024)
Ultra-Sensitive, Self-powered, CMOS-Compatible Near-Infrared Photodetectors for Wide-Ranging Applications
in Advanced Functional Materials
| Description | Collaboration on materials growth |
| Organisation | University of Oxford |
| Department | Department of Chemistry |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | This is a collaboration with Prof. Simon Clarke through a joint CDT student (Georgia Fields). The value of the financial contributions are the ones directly provided by the CDT as part of her research project. The collaboration focuses on developing single crystals of BiOI for photon counting detection. My group provides the expertise on radiation detector development, and optoelectronic characterisation. |
| Collaborator Contribution | Prof. Simon Clarke is an expert in single crystal growth and characterisation by diffraction techniques. We are jointly supervising the DPhil student. |
| Impact | This project is just starting |
| Start Year | 2025 |
| Description | Collaboration with 5N Plus on radiation detector development |
| Organisation | 5N Plus (UK) |
| Country | United Kingdom |
| Sector | Private |
| PI Contribution | We are providing the materials and technology development for BiOI X-ray detectors. This is the focus of this project. |
| Collaborator Contribution | 5N Plus are providing their views from a commercial perspective on the BiOI X-ray detectors, providing feedback on the direction we are taking. They are also able to provide us with links to their customers in the industry when we are ready to spin out. |
| Impact | None yet, this collaboration has just started |
| Start Year | 2024 |
| Description | Collaboration with University at Buffalo, USA for detector materials characterization |
| Organisation | University at Buffalo |
| Country | United States |
| Sector | Academic/University |
| PI Contribution | The BiOI detector materials were synthesized, and the detectors were fabricated at the University of Oxford. |
| Collaborator Contribution | The electrical properties of the detectors, including their low-temperature behavior, are characterized at the University at Buffalo. The University of Buffalo research group is exploring alternative BiOI thick film deposition techniques, including polymer-assisted deposition. |
| Impact | NA |
| Start Year | 2024 |
| Description | Collaboration with University of Cambridge for detector materials characterization |
| Organisation | University of Cambridge |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | The detector materials were synthesized, and the detectors were fabricated at the University of Oxford. |
| Collaborator Contribution | The electrical properties of the detectors, including their low-temperature behavior, are characterized at the University of Cambridge. The research group at the University of Cambridge is exploring alternative BiOI thick film deposition techniques, including epitaxial growth with low-defect-density using pulsed laser deposition and sputtering. |
| Impact | NA |
| Start Year | 2024 |
| Description | Fabrication and characterization of BiOI radiation detectors in collaboration with detector development group, Rutherford Appleton Laboratory, STFC. |
| Organisation | Rutherford Appleton Laboratory |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | We synthesized polycrystalline BiOI powder using a solid-state method and then pressed it into wafers of the desired thickness and dimensions. The material properties were systematically optimized and characterized for radiation detection. To evaluate X-ray detection performance, we fabricated a single-pixel device, while multi-pixel devices were developed for X-ray imaging. |
| Collaborator Contribution | The BiOI X-ray detector was tested using various ionizing radiation and X-ray sources at STFC. Currently, the fabrication and characterization of the multipixel X-ray imager are in progress. |
| Impact | The research is currently in progress. |
| Start Year | 2024 |