Researchers Developing Prototype of Next-Gen Night Vision Technology
Three University of Arkansas researchers — electrical engineering professor Shui-Qing “Fisher” Yu, Distinguished Professor Greg Salamo, and Jin Hu, assistant professor of physics — will collaborate with the Navy Surface Warfare Research Center, Crane Division, and local company Arktonics to use the semiconductor silicon germanium tin in designing and building a prototype of a superior and less-expensive infrared camera. The military uses infrared imaging technologies for night vision technology.
A $4.4 million grant from the U.S. Office of Naval Research will pay for specially designed equipment that will help the team develop the infrared imaging sensor array made of silicon germanium tin. The team will then integrate this array with a complementary metal oxide semiconductor (CMOS) on the same chip. CMOS technology is used for making integrated-circuit chips for microprocessors, controllers and other digital and analog circuits, including image sensors. The combination is more effective at harnessing ambient light, an essential element in night vision technology.
Current technologies rely on semiconducting alloys such as mercury cadmium telluride and other material-based photodetectors. These alloys have several limitations, including a complex and expensive manufacturing process, low production yield, and poor uniformity over large areas. These limitations negatively affect wide-range infrared visibility, especially in areas with poor environmental conditions, such as sandy or hazy environments. These technologies also cannot integrate an infrared camera and other necessary electronics on the same chip, which increases cost and decreases reliability, efficiency, and speed.
By more efficiently harnessing light, silicon germanium tin on silicon substrates is potentially a better solution. Yu has worked with silicon germanium tin for more than a decade. In 2016, he and colleagues reported the fabrication of a first-generation, “optically pumped” laser, meaning the material was injected with light, similar to an injection of electrical current. Yu was also the first to report an “electrical excited” germanium tin laser.
Using molecular beam epitaxy, Salamo has been growing semiconductor nanostructures for more than 20 years. He is well known for his work on quantum wells, dots and wires. Meanwhile, Hu has developed and fabricated new quantum materials and investigated their novel quantum properties.
Top Stories
INSIDERElectronics & Computers
Army Launches CMOSS Prototyping Competition for Computer Chassis and Cards
INSIDERSoftware
The Future of Aerospace: Embracing Digital Transformation and Emerging...
ArticlesAerospace
Making a Material Difference in Aerospace & Defense Electronics
INSIDERRF & Microwave Electronics
Germany's New Military Surveillance Jet Completes First Flight
ArticlesAerospace
Microchip’s New Microprocessor to Enable Generational Leap in Spaceflight...
EditorialConnectivity
Webcasts
Power
Phase Change Materials in Electric Vehicles: Trends and a Roadmap...
Automotive
Navigating Security in Automotive SoCs: How to Build Resilient...
Automotive
Is Hydrogen Propulsion Production-Ready?
Unmanned Systems
Countering the Evolving Challenge of Integrating UAS Into Civilian Airspace
Power
Designing an HVAC Modeling Workflow for Cabin Energy Management and XiL Testing
Defense
Best Practices for Developing Safe and Secure Modular Software