# The Rapid-Production of the High-Performance and Affordable Cadmium Telluride and Cadmium Zinc Telluride for Medical Imaging Applications.

> **NIH NIH R44** · RADIATION DETECTION TECHNOLOGIES, INC. · 2024 · $905,711

## Abstract

1 The high spatial-resolution and energy-resolution of cadmium zinc telluride (CZT) and cadmium telluride
 2 (CdTe), compared to that of scintillators, offers superior image quality in Nuclear medicine and X-ray
 3 imaging applications, i.e. SPECT, PET, CT, Bone Densitometry, Oncology, Dental imaging, Airport
 4 security, etc. CZT and CdTe remain the desired choice for room-temperature radiation detection, but it is
 5 limited by high-cost and availability resulting from low yield and long production times associated with
 6 commercial growth techniques, i.e. the Traveling Heater Method (THM). However, the application of the
 7 Accelerated Crucible Rotation Technique (ACRT) growth method developed at WSU has proven to
 8 produce industrial quality, high-performance CdTe/CZT. This recently developed growth method not only
 9 allows CdTe/CZT to be grown with the same quality as material grown by THM, but also at growth rates
10 approximately 10-20 times faster than THM. Specifically, CdTe/CZT is grown by THM at a rate of
11 approximately 1-3 mm per day, whereas CdTe/CZT growth by ACRT can be accomplished at much faster
12 rates of approximately 1-3 mm per hour. THM-grown CdTe/CZT requires a lower growth temperature for
13 high-quality devices, which results in highly off-stoichiometric melts, thereby inducing the need for
14 postprocessing. These major challenges associated with the crystal growth of CdTe/CZT have been
15 overcome using ACRT. It is proposed here to further develop the ACRT growth process by introducing
16 crystal seeding in the ACRT system for CdTe and scale this process to commercial-grade levels while
17 continuing to improve the CdTe device properties for high-flux SPECT/CT applications. Chlorine doping
18 will be further explored and optimized to achieve high resistivity and high mobility-lifetime CdTe devices.
19 Numerous CdTe:Cl ingots will be grown, and devices will be produced from these ingots (cross strip and
20 commercial pixel patterns). Devices will be sent to commercial partners and customers for validation in
21 effort to integrate into commercial imaging systems. A prototype SPECT/CT system will be designed, built,
22 and images will be collected. The medical/diagnostic imaging market is projected to cross $55.7 billion by
23 2025. Stakeholders in the medical imaging market need CdTe/CZT devices now. The fruition of this project
24 will be a significant reduction (>3x) of industrial-grade material costs by increasing the yield, reducing the
25 growth time, and eliminating post-growth anneal treatments currently used by industry. With the fast-
26 production time and high-performance of the CdTe/CZT produced in this effort, (1) the medical imaging
27 market will finally have a fast turnaround time and consistent high-performance material that can easily be
28 obtained, (2) a >3x price reduction is projected for CdTe/CZT, and (3) Stakeholders will have access to an
29 affordable, high-performance CdTe/CZT material tha...

## Key facts

- **NIH application ID:** 10933546
- **Project number:** 5R44EB029280-03
- **Recipient organization:** RADIATION DETECTION TECHNOLOGIES, INC.
- **Principal Investigator:** LARS R FURENLID
- **Activity code:** R44 (R01, R21, SBIR, etc.)
- **Funding institute:** NIH
- **Fiscal year:** 2024
- **Award amount:** $905,711
- **Award type:** 5
- **Project period:** 2023-09-22 → 2026-01-31

## Primary source

NIH RePORTER: https://reporter.nih.gov/project-details/10933546

## Citation

> US National Institutes of Health, RePORTER application 10933546, The Rapid-Production of the High-Performance and Affordable Cadmium Telluride and Cadmium Zinc Telluride for Medical Imaging Applications. (5R44EB029280-03). Retrieved via AI Analytics 2026-05-25 from https://api.ai-analytics.org/grant/nih/10933546. Licensed CC0.

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