Army, Argonne Scientists Explore Nanoparticles for Future Weapon Systems

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Source: U.S. Army, https://api.army.mil/e2/c/images/2021/02/22/4a4d5942/original.jpg
Source: U.S. Army, https://api.army.mil/e2/c/images/2021/02/22/4a4d5942/original.jpg

March 15, 2021 | Originally published by U.S. Army on February 25, 2021

ABERDEEN PROVING GROUND, Md. – Material scientists from the U.S. Army and Department of Energy conducted a study of plasma-treated aluminum nanoparticles with the goal of improving future propellants and explosives.

Researchers from the U.S. Army Combat Capabilities Development Command, known as DEVCOM, Army Research Laboratory, and the Center for Nanoscale Materials at the Argonne National Laboratory investigated a new class of surface-engineered aluminum nanoparticles. They published their findings in the peer-reviewed Journal of Applied Physics for a special issue, “Fundamentals and Applications of Atmospheric Pressure Plasmas.” The journal featured the article on the cover of its Feb. 14, 2021, issue.

“The ultimate goal of the effort is to extend the range and disruptive power of Army weapon systems,” said Dr. Chi-Chin Wu, a materials scientist at the laboratory. Wu leads this effort and is the first author of the article. “The paper presents results that support ongoing investigations of aluminum nanoparticles for use as novel energetic ingredients in propellant and explosive formulation.”

“The study exploits plasma-based surface treatment and chemical synthesis techniques,” she added.

“Images and data obtained from two state-of-the-art transmission electron microscopes at the Center for Nanoscale Materials at the Argonne National Laboratory revealed valuable information on oxide shell phase transformation and the dispersive nature of the deposited carbonaceous materials,” Wu said. “This provides tremendous insight for further optimization.”

The new plasma approach enhances the reactivity of commercial 40-60 nanometer particles. For comparison, a human hair is typically 60,000 nanometers in width. According to Wu, the method involves first treating with a helium plasma to etch away a significant portion of their inert oxide shell and then treating with a helium/carbon monoxide plasma to deposit a reactive surface coating.

“Plasma science is a fascinating emerging technology for many applications but has yet to be sufficiently explored in the energetics community,” she said. “All this is done in a custom dielectric barrier discharge plasma reactor. The resultant particles were then characterized by high-resolution transmission electron microscopy revealing important nanoscale surface and chemical composition features. We are constantly seeking new energetic materials with higher energy densities and faster energy release rates.”

Plasma treatment and synthesis, coupled with comprehensive material characterization, is critically important for optimizing methodologies and materials for scale-up and transition, she said.

Dr. Rose Pesce-Rodriguez, also from the laboratory and a co-author of the study, said the plasma approach developed by Wu has opened new possibilities for the U.S. Army to effectively surface-engineer metallic nanoparticles for energetics applications.

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