Published: 
By  The Office of Communications at the UVA School of Engineering and Applied Science
Kory Burns
Kory Burns studies the structure of materials in his BEAM (Burns' Electronic and Advanced Materials) Lab in order to modify them for the applications in which they were designed to perform. His team’s latest approach is to use machine learning to identify defects that would otherwise go unspotted through human identification in transmission electron micrographs. (Photo by Tom Daly)

Kory Burns, an assistant professor at the University of Virginia School of Engineering and Applied Science, is a leader in materials science who is using artificial intelligence to improve materials characterization. 

He and his collaborators, representing multiple universities and national labs, detailed their innovative new technique studying how to better determine the nanoscale effects of radiation on materials in a recent paper in APL [Applied Physics Letters] Machine Learning

UVA collaborates with Oak Ridge National Laboratory, which co-hosts Burns’ research.

The research features one of the largest labeled datasets of its kind and promises to advance the understanding of how materials behave not only under irradiated conditions, but potentially under other types of extremes as well.

Industries such as renewable energy, space exploration and advanced electronics stand to benefit from improved materials that can better withstand harsh environments. 

For everyday consumers, the breakthrough could mean longer-lasting batteries, more reliable electronics and safer medical devices.

“Defects caused by radiation at the nanoscale can significantly affect performance and structural longevity,” said Burns, who became an assistant professor in August after joining the Department of Materials Science Engineering in 2022 as a Rising Scholar Research Scientist. “By examining the fundamental interactions within materials, we can devise better strategies to extend their lifetime.”

Tiny and Fast Changes

Transmission electron microscopy, or TEM, is an imaging technique that uses a beam of electrons to pass through very thin samples, often referred to as thin films because they’re so flat. 

TEM can reveal atomic-level, nanoscale details about a specimen that are impossible to view with a light microscope. That might include crystal structures or small changes that occur due to surface interactions, making TEM an essential tool in materials science.

Scientists can also employ convolutional neural networks, or CNNs, to study changes over time. Unlike traditional models, CNNs learn from large groups of data all at once.

Burns’ team combined the two approaches, comparing its CNN results with traditional TEM images to assess the model's effectiveness at capturing nanoscale interactions.

“Our model reduces human error, accelerates analysis and quantifies rapid reactions,” Burns said. “However, accurate results depend on proper data preparation and fine-tuning model settings.”

Machine Learning Workflow Diagram from APL Machine Learning
Burns and collaborators' machine learning workflow diagram, published in APL Machine Learning

Metals Differ in Their Defects

Using advanced time-series imaging techniques with the transmission electron microscope, the team compiled over 1,000 images capturing more than 250,000 defects formed during ion irradiation. These defects included helium bubbles and planar defects known as “dislocation loops.”

Key findings from the research highlight the complexities of defect classification. The study revealed that defects in materials such as copper and gold exhibit different behaviors compared to those in palladium. This distinction underscores the need for specialized analytical models to accurately study these materials under radiation.

One major challenge the researchers encountered was “drift,” where images can shift due to changes in the experimental environment, leading to potential inaccuracies. To address this, the team proposed the use of advanced techniques like denoising autoencoders, which help clean up images and improve data reliability.

Burns collaborated on the research with engineers and other experts from the University of California-Berkeley, Sandia National Laboratories, Massachusetts Institute of Technology, Los Alamos National Laboratory, University of Florida, University of Michigan, Lawrence Berkeley National Laboratory and the University of Tennessee-Knoxville.

Improving Semiconductors

Kory Burns is also a valued mentor to his graduate students, who often learn on-site at Oak Ridge National Laboratory. Recently, Burns guided Ph.D. student Elaina Truhart, an Olsen Fellow, in researching electron-phonon coupling in semiconductors. This phenomenon is crucial for understanding material reactions under varying temperatures. Their work, presented at the American Physical Society’s March meeting, aims to enhance electric current mobility and thermal conductivity for next-generation electronic devices.