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Grain Interface Functional Design to Create Damage Resistance in Polycrystalline Metallic Materials

Project Personnel

Curt Bronkhorst

Principal Investigator

University of Wisconsin, Madison

Nan Chen

University of Wisconsin, Madison

Siddhartha Pathak

Iowa State University of Science and Technology

Marko Knezevic

University of New Hampshire

William Musinski

Air Force Research Laboratory

Manny Gonzales

Air Force Research Laboratory

Funding Divisions

Division of Materials Research (DMR), Air Force Research Laboratory (AFRL), Established Program to Stimulate Competitive Research (EPSCoR), Division of Civil, Mechanical, and Manufacturing Innovation (CMMI)

Even though polycrystalline metallic materials are ubiquitous in daily life, when and where metallic structural components damage and fail is difficult to predict, which generally leads to overdesign. 

One form of damage – ductile damage – takes place in materials which are easily plastically deformed by formation of voids and localized shear bands. The initiation of these voids is strongly influenced by the internal constitution of the aggregate composite made up of single crystals comprising the polycrystalline metal. High-purity metals often form voids at the boundaries between single crystals, but it is not known why. 

This Designing Materials to Revolutionize and Engineer our Future (DMREF) award supports the fundamental study of voids-based ductile damage in high-purity metals to enable the manufacture of materials for specific applications with significantly reduced propensity for void formation. In addition, this project will facilitate collaboration with the Air Force Research Laboratory to pursue design of new materials and manufacturing techniques for strategic purposes. This highly collaborative project will also allow students the opportunity to engage on three campuses, the Air Force Research Laboratory, and a couple of Department of Energy Laboratories to assist in educating the next generation of scientists and engineers in strategically important disciplines. Designing material interfaces to resist formation of voids during tensile deformation will be a significant contribution to the Materials Genome Initiative.

Publications

Statistical evaluation of microscale stress conditions leading to void nucleation in the weak shock regime
N. J. Schmelzer, E. J. Lieberman, N. Chen, S. D. Dunham, V. Anghel, G. T. Gray, and C. A. Bronkhorst
5/1/2025
Quantifying power partitioning during void growth for dynamic mechanical loading in reduced form
N. J. Schmelzer, E. J. Lieberman, N. Chen, and C. A. Bronkhorst
5/1/2025
Crystal plasticity finite element simulations of nanoindentation and simple compression for yielding of Ta crystals
S. Izadpanah Najmabad, O. F. Olanrewaju, S. Pathak, C. A. Bronkhorst, and M. Knezevic
8/1/2024
Deformation, dislocation evolution and the non-Schmid effect in body-centered-cubic single- and polycrystal tantalum
S. Lee, H. Cho, C. A. Bronkhorst, R. Pokharel, D. W. Brown, B. Clausen, S. C. Vogel, V. Anghel, G. T. Gray, and J. R. Mayeur
4/1/2023

View All Publications

U.S. National Science Foundation and NSF DMREF, Materials for Our Future

This material is based upon work supported by the U.S. National Science Foundation Award No. 2015237. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the U.S. National Science Foundation. This site is maintained collaboratively by principal investigators with NSF DMREF awards, independent of the NSF.