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Corning uses neutrons to reveal how ‘atomic rings’ help predict glass performance

Researchers at Corning have found that understanding the stability of the rings of atoms in glass materials can help predict the performance of glass products.
Researchers at Corning have found that understanding the stability of the rings of atoms in glass materials can help predict the performance of glass products. Credit: ORNL, U.S. Dept. of Energy

Glass is being used in a wider range of high-performance applications, including those for consumers and industry, military and aerospace electronics, coatings and optics. Because of the extreme precision demanded for use in products such as mobile phones and jet aircraft, glass substrates must not change their shape during the manufacturing process. 

Corning Incorporated, a manufacturer of innovative glass, ceramics and related materials, invests a tremendous amount of resources into studying the stability of different types of glass. Recently, Corning researchers found that understanding the stability of the rings of atoms in glass materials can help them predict the performance of glass products. This capability is important because the most widely used glass is silicate glass, which consists of different sizes of atomic rings connected in three dimensions.

Conducting neutron scattering experiments at the Department of Energy’s Oak Ridge National Laboratory, ORNL and Corning scientists discovered that as the number of smaller, less-stable atomic rings in a glass increases, the instability, or liquid fragility, of the glass also increases. The results of the neutron experiments, published in Nature Communications, reveal a clear correlation between the medium-range atomic ring structure of a silicate glass and its liquid fragility. The viscosity of the liquid glass changes considerably when it is cooled to the glass transition temperature. A more fragile liquid will have a larger viscosity change with a given temperature change.

The Corning research team, from left, included Nicholas Smith, Ying Shi, Douglas Allan and Ozgur Gulbiten. Credit: Corning Incorporated
The Corning research team, from left, included Nicholas Smith, Ying Shi, Douglas Allan and Ozgur Gulbiten. Credit: Corning Incorporated

“Previously, the mechanism driving glass transitions had eluded scientists,” said Ying Shi, the corresponding author of the study’s paper and research associate at Corning. “There was no clear understanding as to why some types of glass solidified faster or slower.”

Shi and her collaborators from Corning, the University of California, Los Angeles, and the University of Oxford worked with the NOMAD neutron diffractometer beamline scientists at ORNL’s Spallation Neutron Source to study aluminosilicate glass, which is commonly used by industry. 

Using a recently developed and validated neutron scattering data analysis tool, RingFSDP, the team identified key patterns in the collected data that revealed the relationship between the liquid fragility in the glass and its atomic ring stability.

RingFSDP is a free, open-source program developed by Corning and ORNL scientists to study the atomic ring structures of silicate glass. It derives ring-size distributions in silicate glass from the shape of the first sharp diffraction peak in the neutron diffraction data.

“Connecting the glass transition temperature range to underlying structural features of a glass will have a significant impact on glass design and production,” said Douglas Allan, the paper’s co-author and a research fellow at Corning. “Our work shows a clear correlation between the atomic ring structure of a glass and its glass transition temperature range and therefore the performance features of the glass.” 

The study included researchers from the Science and Technology Division at Corning, the Physics of Amorphous and Inorganic Solids Laboratory in the Department of Civil and Environmental Engineering at the University of California, Los Angeles, the Neutron Scattering Division at ORNL’s SNS and the Physical and Theoretical Chemistry Laboratory at the University of Oxford.

SNS is a DOE Office of Science user facility.

UT-Battelle manages ORNL for DOE’s Office of Science, the single largest supporter of basic research in the physical sciences in the United States. The Office of Science is working to address some of the most pressing challenges of our time. For more information, please visit energy.gov/science.