Publications
Microstructural Modeling of Brittle Materials for Enhanced Performance and Reliability
Teague, Melissa C.; Teague, Melissa C.; Rodgers, Theron R.; Rodgers, Theron R.; Grutzik, Scott J.; Grutzik, Scott J.; Meserole, Stephen M.; Meserole, Stephen M.
Brittle failure is often influenced by difficult to measure and variable microstructure-scale stresses. Recent advances in photoluminescence spectroscopy (PLS), including improved confocal laser measurement and rapid spectroscopic data collection have established the potential to map stresses with microscale spatial resolution (%3C2 microns). Advanced PLS was successfully used to investigate both residual and externally applied stresses in polycrystalline alumina at the microstructure scale. The measured average stresses matched those estimated from beam theory to within one standard deviation, validating the technique. Modeling the residual stresses within the microstructure produced general agreement in comparison with the experimentally measured results. Microstructure scale modeling is primed to take advantage of advanced PLS to enable its refinement and validation, eventually enabling microstructure modeling to become a predictive tool for brittle materials.