Improving our ability to see in the dark through unique materials

ASU professors receive MURI award to research better infrared imaging technology


May 9, 2019

Brass, bronze and steel are metal alloys in which the combination of chemical elements — copper and zinc, copper and tin, iron and carbon, respectively — create unique properties, such as high strength and corrosion resistance, that can be used for particular purposes.  

Arizona State University Professor Yong-Hang Zhang and Associate Professor Andrew Chizmeshya are exploring these purposes as part of a U.S. Department of Defense Multidisciplinary University Research Initiative effort. They will study the fundamental material properties of silicon-germanium-tin (SiGeSn) alloys for use in the next generation of lighter, faster and more energy-efficient infrared imaging technology. portrait of Yong Hang Zhang in a lab As part of a U.S. Department of Defense Multidisciplinary University Research Initiative effort, Arizona State University Professor Yong-Hang Zhang will study the quality and stability of silicon-germanium-tin alloys and develop innovative device architectures for infrared applications. Photo by Erika Gronek/ASU Download Full Image

The DOD MURI program supports multidisciplinary university research teams aiming to better understand or achieve fundamental research objectives that have never been done before. Many previous MURI projects have yielded significant breakthroughs, sustained scientific advancement and fostered the growth of graduate students in cutting-edge fields.

In 2019, the DOD issued 24 high-profile, highly competitive MURI awards totaling $169 million. Zhang and Chizmeshya will receive approximately $2 million of a $7.5 million MURI award shared with the lead institution University of Arkansas at Fayetteville and collaborators at Dartmouth University, the University of Massachusetts, Boston and George Washington University.

“The MURI program is one of the most competitive and most exciting programs from the DOD for university professors,” said Zhang, a professor of electrical engineering in the School of Electrical, Computer and Energy Engineering, one of the six Ira A. Fulton Schools of Engineering, and the director of ASU’s Center for Photonics Innovation. “This is my fourth MURI award related to semiconductor optoelectronic materials and devices, a clear indication of ASU’s strength in photonics research. We’re tackling a very challenging problem, so now we need to roll up our sleeves and get to work.”

The next generation of infrared imaging technology

Semiconductor materials — an essential component of electronic technologies such as lasers, solar cells and transistors — dominate the infrared imaging industry.

Current state-of-the-art infrared technology made with semiconductor alloys of mercury-cadmium-telluride, or elements from groups three and five in the periodic table, gives users the ability to see in both daylight and darkness and plays a critical role in U.S. military defense systems and commercial applications.

While infrared devices have significant potential to increase visibility across multiple platforms, current technologies that use semiconductor alloys are limited in performance by complex manufacturing operations, inefficient production processes, poor uniformity and high fabrication costs. These limitations hinder widespread use of the technology in military and civilian sectors.

man at his desk

Andrew Chizmeshya

“SiGeSn alloys are a relatively new class of semiconducting materials that will allow the development of the next generation of high-speed detectors, emitters and modulators for applications in optoelectronic telecommunications and night vision,” said Chizmeshya, an associate professor of chemistry in ASU’s School of Molecular Sciences. “They are mostly composed of germanium, but the judicious addition of silicon and tin allows new electronic behavior, such as direct band gap, to be accessed.”

Similar to laying bricks to build a wall, researchers can add consecutive layers of semiconducting materials to fabricate a working device, like a cell phone chip. SiGeSn alloys allow multiple layers to be fabricated coherently leading to new semiconductor architectures with previously unattainable properties, such as achieving the longest range of infrared detection.

“If we can improve the SiGeSn material and put it on a silicon substrate with very large-scale integration, the whole system can outperform all current infrared technology at very low costs,” Zhang said. “It can enable people to see infrared — something human eyes do not see.”

To design, fabricate and demonstrate SiGeSn as the new semiconductor alternative for infrared technology, the MURI team has to overcome a range of material challenges. How do they reach middle-wave infrared wavelengths? Once achieved, how do they improve the material’s performance? When the SiGeSn material system exhibits quality and stability, how can they use it to make high-performance devices?

Additionally, Chizmeshya says thermodynamic data on SiGeSn alloys is exceedingly scarce. So, the research team will develop and apply a specialized, ground-up thermodynamic framework to shed new light on the origins of alloy stability and ultimately map out a phase diagram for the SiGeSn systems. The methodology could later be applied to other complex alloy systems.

If the project is successful, low-cost and high-performance infrared technologies with SiGeSn will have a tremendous impact for the U.S. Department of Defense. For instance, aircraft can be equipped with more efficient and cost-effective thermal infrared imaging to improve battlefield surveillance in poor visibility conditions. Additionally, soldiers and defense vehicles can be armed with ground-based vision systems to detect threats and vulnerabilities with higher accuracy and precision.

The effect of using SiGeSn alloys will reach well beyond the defense applications. Infrared technology can benefit medical care, surveillance, search and rescue applications, self-driving vehicles, meteorology and climatology.

Zhang envisions low-cost night vision technologies based on SiGeSn will be widely used by cars, trucks and other autonomous vehicles in less than 10 years. Car accidents due to limited visibility at night, in fog or in dust storms will be significantly reduced, saving lives and improving safety.

people working in lab

Under the mentorship of Professor Yong-Hang Zhang, Tyler McCarthy (left), an electrical engineering doctoral student, and Zheng Ju, a physics doctoral student, operate a molecular-beam epitaxy machine to grow single-crystal semiconductor thin films and solar cells. Photo by Erika Gronek/ASU

More than a decade of SiGeSn alloy expertise

This MURI Award brings together a multidisciplinary research team working at the frontier of SiGeSn alloys. The team of chemists, civil engineers, electrical engineers, mathematicians and physicists will leverage and build upon years of experience with infrared photonics research to understand fundamental material and device problems for SiGeSn and their low-cost, large-scale manufacturing. 

Shui-Qing "Fisher" Yu, the principal investigator at the University of Arkansas, has expertise in the development of optoelectronic devices with SiGeSn alloys, such as lasers, photodetectors and infrared cameras. He also studies the potential of SiGeSn to improve materials quality and decrease costs for the devices.

Yu graduated from ASU with a doctoral degree in electrical engineering in 2005, earning the prestigious Fulton Schools Palais Outstanding Doctoral Student Award for his work in Zhang’s research group.

Zhang’s research has covered a broad area of optoelectronics, including the growth of semiconductor materials and their structural and optical properties, as well as novel semiconductor device design, fabrication and testing.

For this project, Zhang will seek a better understanding of epitaxial growth techniques, determine the quality and stability of the SiGeSn material and develop innovative device architectures tailored for SiGeSn alloys for infrared applications. Zhang’s expertise as an experimentalist pairs nicely with that of his collaborator and theorist Chizmeshya.

Chizmeshya’s expertise in theoretical solid-state electronics, chemistry and materials science methods will guide the design of new alloys and elucidate their thermodynamic, electronic and structural properties. He’ll use quantum-mechanics-based simulations to study key aspects of the chemical vapor deposition growth process using supercomputers.

“Many of the investigators on this MURI award have worked together and/or separately on various aspects of SiGeSn alloys for more than a decade,” Chizmeshya said. “We will be able to combine our individual expertise and vast collective experience for the first time.”

people posing for photo in lab

Professor Yong-Hang Zhang and his doctoral students in Arizona State University’s MBE Optoelectronics Group. Pictured from left to right: Jia Ding, Zheng Ju, Cheng-Ying Tsai, Zhang and Tyler McCarthy. Photo by Erika Gronek/ASU



Amanda Stoneman

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Making global connections through nursing and health innovation programs

A new unit in the Edson College of Nursing and Health Innovation will work to grow the college’s worldwide reach


May 9, 2019

Looking to expand its international footprint, the Edson College of Nursing and Health Innovation at Arizona State University has created a new unit the Global Health Collaboratory.

The collaboratory’s mission is bold: to develop global collegiate partnerships, expand certificate programs to nontraditional students and grow international student and faculty exchange opportunities. Edson College Sr. Associate Dean Craig Thatcher pictured with Dean Xiulan Wang (left) of the Nursing Program at Xinhua College at Sun Yat-sen University in Guangzhou, China. Edson College Senior Associate Dean Craig Thatcher (center) pictured with Dean Xiulan Wang (second from left) of the Nursing Program at Xinhua College at Sun Yat-sen University in Guangzhou, China. Photo courtesy Craig Thatcher Download Full Image

And that’s just the beginning.

Led by Edson College Senior Associate Dean Craig Thatcher, preliminary work to identify potential global collegiate partners is already underway. This spring, Thatcher visited China as part of a 10-day ASU delegation trip that included Kay Faris, senior associate dean of the W. P. Carey School of Business, and Angela Zhao, senior project manager with the Office of the Provost to meet with deans and administrators at several universities there.

“I think there are opportunities for academic partnerships and to recruit more international students interested in health and health care,” said Thatcher. “There are also research opportunities with these universities, too, so I believe there’s a lot of potential mutual benefits for Edson College to be in China.”

The four universities Thatcher toured were:

  • Capital Medical University.

  • Xi’an Jiaotong University.

  • Sichuan University.

  • Xinhua College of Sun Yat-sen University.

He said each institution offers collaborative opportunities and they were all equally open to the higher-level nursing curricula and overall health education expertise Edson College can provide.

“I made this visit as an exploratory step. Next up is to decide what Edson College wants to do with each of these universities and then develop specific agreements to advance what would be best for all involved,” Thatcher said.

As a result of this trip, Edson College will be hosting 22 undergraduate students from Sichuan University on the ASU Downtown Phoenix campus in July to participate in the Global Health Innovators Program, which Thatcher and his team developed specifically for the participants. The program will focus on entrepreneurship and innovation in health and health care, cultural exploration and English language experiences for the students.

In addition to China, Edson College is also actively pursuing programs and partnership opportunities in Vietnam, Honduras and Kenya.

“We want to provide intercultural experiences for domestic students while also giving international students exposure to our culture and health care practices,” said collaboratory Senior Director Amy Fitzgerald. “Our goal is to further the practice of nursing and health care worldwide.”

Closer to home, the unit is also beginning to foster relationships with fellow university partners like Thunderbird School of Global Management and the Graduate College in order to maximize local resources and expertise, especially in the areas of global health management and innovation.  

Ultimately, the collaboratory will help Edson College better respond to the universal demand for advanced level nursing and health education.

“Our new unit aligns with the university’s goals related to global engagement, and while we’ve done some of this work in the past, we want to be more proactive and strategic going forward,” Thatcher said.

Amanda Goodman

Senior communications specialist, Edson College of Nursing and Health Innovation

602-496-0983