UAB led research tests stability of 3D-printed super alloy under extremes

What makes structures and materials designed for extreme environments reliable?

Recent research led by the University of Alabama at Birmingham and published in Scientific Reports details developments in the understanding of additively manufactured materials under high pressures through the use of high-resolution imaging and computer simulations.

Yogesh Vohra, Ph.D., professor in the Department of Physics and associate dean for Research and Innovation in the College of Arts and Sciences, serves as the principal investigator for the Center for Additively Manufactured Complex Systems under Extremes.

To produce better materials for human use in extreme environments, CAMCSE studies how 3D-printed materials perform under extremes of pressures, temperatures, and high-velocity impact or shock compression.

Using focused ion beam technology to extract a compressed sample a few nanometers thick, the electron microscopy observations confirmed the irreversibility of the phase transformation. The nano-layer arrangement remained undisturbed even after exposure to extreme pressures.

Vohra says the published research focuses on the fundamental structural reasons behind the high strength and ductility of 3D-printed alloys.

“In particular, how crystal structure changes under high pressures might impact the mechanical properties of 3D-printed alloys,” Vohra said. “The electron microscopy study in this paper is significant as it established for the first time that the nanostructured layered structure is maintained after exposure to pressure and there is no change in chemical composition of individual layers.”

This research will allow for developments in the design of additively manufactured materials for extreme high temperatures in aerospace and power plant applications, resilient structures under hypervelocity impacts, and high-radiation environments in nuclear reactors.

Vohra says he is excited about this development in CAMCSE as it represents advancement in the understanding of crystal structure changes induced by high pressure and highlights the significance of collaboration.

“This paper represents collective expertise of four different academic institutions applied to 3D-printed super alloys under extremes,” Vohra said. “Working across science and engineering disciplines on a common problem is a notable achievement of CAMCSE and at the same time provides training opportunities to UAB graduate students.”

CAMCSE has four academic partners: University of Massachusetts-Amherst, Stanford University, University of California-Irvine and Tuskegee University.

This article originally appeared in UAB News 8/26/2024

Dr. Melissa Sims Joins the Faculty in the Physics Department at UAB

Dr. Melissa Sims is joining as a tenure-track Assistant Professor in the Department of Physics at the University of Alabama at Birmingham beginning August 2024. Dr. Sims will also be affiliated with DOE NNSA funded Center of Excellence CAMCSE at UAB (https://sites.uab.edu/camcse/). Previously, she was an NSF EAR Postdoctoral Fellow at Johns Hopkins University with a visiting scientist appointment at Lawrence Livermore National Laboratory. Hailing from South Carolina, Dr. Sims earned bachelor’s degrees from the College of Charleston and the University of South Carolina and completed her master’s and doctorate at Stony Brook University.

Dr. Sims’s research focuses on planetary interiors, meteorite impacts, and the behavior of materials undergoing extreme conditions. Her work is dedicated to unraveling the mysteries surrounding solar system formation and planetary evolution and investigates the unique mechanical, thermal, and chemical responses of materials subjected to shock conditions. During her doctorate, Dr. Sims honed her expertise in quasi-static high-pressure techniques, employing in-operando studies to examine the effects of orientation, texture, strain-rate, and pressure on the nucleation and growth of mineral phases commonly found in meteorites.  She has broadened her research to include dynamic experiments using laser and gas-gun platforms, leveraging recent technological advancements and newly available national and international facilities.

Outside of her academic pursuits, Dr. Sims finds joy in playing the violin, riding her horse, and breeding exotic fish.