Major DoE grants help two Nebraska Engineering teams expand innovative energy research

Calendar Icon Nov 29, 2022      Person Bust Icon By Karl Vogel     RSS Feed  RSS Submit a Story

Nebraska Engineering researchers - (top photo from left) Jongwan Eun, Yuris Dzenis, and Seunghee Kim; and (bottom photo from left) Peter Sutter and Eli Sutter. (Photos by University Communication and Marketing)
Nebraska Engineering researchers - (top photo from left) Jongwan Eun, Yuris Dzenis, and Seunghee Kim; and (bottom photo from left) Peter Sutter and Eli Sutter. (Photos by University Communication and Marketing)

More than $1.4 million in funding from the U.S. Department of Energy (DOE) will allow two College of Engineering teams to expand innovative energy-related research in partnership with national laboratories.

The DOE recently announced $21 million in funding for 29 new projects through Established Program to Stimulate Competitive Research (EPSCoR). The University of Nebraska-Lincoln is one of only four institutions to have two projects chosen for this funding program:

Jongwan Eun, associate professor of civil and environmental engineering; Seunghee Kim, assistant professor of civil and environmental engineering; and Yuris Dzenis, R. Vernon McBroom Professor in mechanical and materials engineering, received $675,000 over three years to investigate how the use of inorganic microfibers can make a more resilient barrier material to improve the long-term storage capabilities of vessels that contain high-level nuclear waste and spent nuclear fuel (SNF).

Peter Sutter, professor of electrical and computer engineering, and Eli Sutter, professor of mechanical and materials engineering, received $747,387 over three years to study new classes of semiconductors for use in in photovoltaics and information processing.

"We have worked hard to become leaders in the field of layered two-dimensional semiconductors and have developed advanced electron microscopy techniques to be able to study them," said Peter Sutter. "The grant provides an opportunity to deepen our partnership with Oak Ridge (National Laboratories) that opens access to new capabilities and to unique sources of expertise."

Peter and Eli Sutter
Peter Sutter, professor of electrical and computer engineering, and Eli Sutter, professor of mechanical and materials engineering, are studying how new classes of materials can be bonded to create semiconductors that more efficiently produce electric current in photovoltaic cells. (Craig Chandler/University Communication and Marketing)

The Sutters' new project is built on previous research in which they developed approaches for synthesizing new classes of layered semiconductors as well as for joining them in engineered "heterostructures" with atomically precise boundaries (or "interfaces").

The new research, Peter Sutter said, builds on these advances to realize new challenges, such as the transition to complex systems that combine different functionality, for instance absorption of light and efficient separation of light-induced charges at interfaces in devices. The second important focus is to develop advanced electron microscopy techniques that can overcome the diffraction limit in measuring the interaction semiconductors with light.

"With ordinary approaches, one can see or probe light-induced phenomena down to the order of the wavelength of the light, which is only a fraction of a micrometer. If we want to go to much smaller scales – ultimately down to the atomic scale – traditional methods don't work," Peter Sutter said. "Understanding these processes is of great importance to fields such as solar energy conversion and quantum information processing."

Jongwan Eun, Yuris Dzenis and Seunghee Kim pose in Dzenis’ lab as Benjamin Bashtovoi and Mikhail Kartashov test carbon-fiber samples
Jongwan Eun (center left), Yuris Dzenis (center) and Seunghee Kim (center right) pose in Dzenis’ lab as Benjamin Bashtovoi (left), a junior mechanical engineering major, and Mikhail Kartashov (right), a graduate student, investigate how inorganic microfibers can make a more resilient barrier material for long-term storage of high-level nuclear waste and spent nuclear fuel. (Craig Chandler/University Communication and Marketing)

In a previous DOE-funded project, Eun and Kim worked with researchers at Sandia National Laboratories to find materials to make the deep geologic disposal and storage of SNF safer.

By adding microfibers to bentonite, a more durable material can be created to minimize cracking that is caused by the high heat of the SNF inside the canister drying the material on the outside.

The new study, they said, strives to understand the mechanical properties of the material as a foundation for developing new and improved barrier materials, especially with extreme soil conditions such as drought.

"We know that dry soil is not favorable to contain these materials, which have to be stored safely for 10,000 years or so," Eun said. "Cracks can lead to leaking, and that is dangerous. That's why we need to understand the interactions of multiple elements, like the mechanical characteristics of fiber bentonite mixture and the surface energy between bentonite clay particles and the fibers, and that will lead to developing better materials."

"We are the first group to add this inorganic fiber to reinforce the bentonite, and we found a good outcome - it can lead to less cracking," Kim said. "We know Nebraska and the United States depend highly on fossil fuels to produce electricity. This grant is very much aligned with the Grand Challenges set by the university, especially in finding more resiliency in our energy systems and working toward decarbonization and a smaller carbon footprint."



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