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| Funder | European Commission |
|---|---|
| Recipient Organization | Katholieke Universiteit Leuven |
| Country | Belgium |
| Start Date | Jan 01, 2024 |
| End Date | Dec 31, 2028 |
| Duration | 1,826 days |
| Number of Grantees | 1 |
| Roles | Coordinator |
| Data Source | European Commission |
| Grant ID | 101117274 |
X-rays are widely applied in medical diagnostics, security screening and scientific research.
The growing demand for X-ray imaging has increased the frequency with which humans are exposed to ionizing X-rays, directly increasing radiation-related health risks.
To minimize these health risks, X-PECT aims to rationally design materials that enable more sensitive X-ray detectors, thus allowing the use of lower operational radiation doses.
Metal halide perovskite (MHP) semiconductors have emerged as a highly promising material class for sensitive X-ray detection.
Besides their easy processing, the popularity of MHPs arises from their outstanding optoelectronic properties, such as strong high-energy X-ray absorption, and efficient charge carrier generation and transport, outperforming current market standards.
However, the intrinsic instability and toxicity of popular lead-based MHPs hinders their large-scale application in sustainable X-ray technology.
X-PECT aims for a fundamental understanding of the intrinsic strengths and limitations of MHPs as photoactive material for X-ray detection.
In this context, X-PECT will address urging scientific hurdles related to toxicity, structural and chemical stability, intrinsic charge carrier transport efficiency, and processing efforts.
The ultimate goal of X-PECT is to rationally develop highly sensitive, sustainable lead-free MHPs through micromanaging their electronic structure by composition and dimensionality engineering.
Tailoring their functionality will be guided by applying a full arsenal of both established characterization techniques and unique (micro)spectroscopy platforms for the full assessment of the structural and photophysical properties to identify and suppress the factor(s) currently limiting the X-ray sensitivity and stability.
Ultimately, selected candidate materials will be processed into a stable, scalable pixelated X-ray demonstrator device with a 20- to 50-fold improved sensitivity and resolution.
Katholieke Universiteit Leuven
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