Publications

Alleman, Coleman A.; Bergel, Guy L.; Foulk, James W.; Karlson, Kyle N.; Manktelow, Kevin M.; Ostien, Jakob O.; Stender, Michael S.; Stershic, Andrew J.; Veilleux, Michael V.

Abstract not provided.

Kalashnikova, Irina; Mota, Alejandro M.; Alleman, Coleman A.; Phlipot, Greg [.

Abstract not provided.

Mota, Alejandro M.; Foulk, James W.; Ostien, Jakob O.; Alleman, Coleman A.; Talamini, Brandon T.

Abstract not provided.

Jones, Reese E.; Alleman, Coleman A.; Frankel, Ari L.; Khalil, Mohammad K.; Heckman, Nathan H.; Boyce, Brad B.; Teichert, Greg T.

Abstract not provided.

Conference Proceedings of the Society for Experimental Mechanics Series

Antoun, Bonnie R.; Alleman, Coleman A.; De La Trinidad, Kelsey E.

We seek to develop a fundamental understanding of dynamic strain aging through discovery experiments to inform the development of a dislocation based micromechanical constitutive model that can tie to existing continuum level plasticity and failure analysis tools. Dynamic strain aging (DSA) occurs when dislocation motion is hindered by the repetitive interaction of solute atoms, most frequently interstitials, with dislocation cores. At temperatures where the interstitials are mobile enough, the atmospheres can repeatedly reform, lock, and release dislocations producing a characteristic serrated flow curve. This phenomenon can produce reversals in the expected mechanical behavior of materials with varying strain rate or temperature. Loss of ductility can also occur. Experiments were conducted on various forms of 304L stainless steel over a range of temperatures and strain rates, along with temporally extreme measurements to capture information from the data signals during serrated flow. The experimental approach and observations for some of the test conditions are described herein.

Ostien, Jakob O.; Alleman, Coleman A.; Foulk, James W.; Karlson, Kyle N.; Manktelow, Kevin M.; Stender, Michael S.; Stershic, Andrew J.; Veilleux, Michael V.; Brown, Arthur B.

Abstract not provided.

Jones, Reese E.; Rizzi, Francesco N.; Templeton, Jeremy A.; Ostien, Jakob O.; Alleman, Coleman A.; Khalil, Mohammad K.; Frankel, Ari L.; Heckman, Nathan H.; Boyce, Brad B.; Teichert, Greg T.; Garikipati, Krishna G.

Abstract not provided.

Jones, Reese E.; Rizzi, Francesco N.; Templeton, Jeremy A.; Ostien, Jakob O.; Alleman, Coleman A.; Khalil, Mohammad K.; Frankel, Ari L.; Heckman, Nathan H.; Boyce, Brad B.; Garikipati, Krishna G.; Teichert, Greg T.

Abstract not provided.

Jones, Reese E.; Rizzi, Francesco N.; Templeton, Jeremy A.; Ostien, Jakob O.; Alleman, Coleman A.; Khalil, Mohammad K.; Frankel, Ari L.; Heckman, Nathan H.; Boyce, Brad B.; Garikipati, K G.; Teichert, G T.

Abstract not provided.

Antoun, Bonnie R.; Alleman, Coleman A.; Sugar, Joshua D.; De La Trinidad, Kelsey E.

Abstract not provided.

Mota, Alejandro M.; Alleman, Coleman A.; Kalashnikova, Irina; Phlipot, Gregory P.

Abstract not provided.

Alleman, Coleman A.; Antoun, Bonnie R.; Foulk, James W.; Lim, Hojun L.; Mota, Alejandro M.; Ostien, Jakob O.

Abstract not provided.

Mota, Alejandro M.; Kalashnikova, Irina; Alleman, Coleman A.

Abstract not provided.

Antoun, Bonnie R.; Alleman, Coleman A.; Sugar, Joshua D.

Abstract not provided.

Khalil, Mohammad K.; Rizzi, Francesco N.; Frankel, Ari L.; Alleman, Coleman A.; Templeton, Jeremy A.; Ostien, Jakob O.; Boyce, Brad B.; Jones, Reese E.

Abstract not provided.

Alleman, Coleman A.; Antoun, Bonnie R.; Foulk, James W.; Mota, Alejandro M.; Sugar, Joshua D.

Abstract not provided.

Alleman, Coleman A.; Boyce, Brad B.; Frankel, Ari L.; Heckman, Nathan H.; Khalil, Mohammad K.; Garikipati, Krishna G.; Jones, Reese E.

Abstract not provided.

Kalashnikova, Irina; Mota, Alejandro M.; Alleman, Coleman A.

Abstract not provided.

Computational Mechanics

Alleman, Coleman A.; Foulk, James W.; Mota, Alejandro M.; Lim, Hojun L.; Littlewood, David J.

The heterogeneity in mechanical fields introduced by microstructure plays a critical role in the localization of deformation. To resolve this incipient stage of failure, it is therefore necessary to incorporate microstructure with sufficient resolution. On the other hand, computational limitations make it infeasible to represent the microstructure in the entire domain at the component scale. In this study, the authors demonstrate the use of concurrent multiscale modeling to incorporate explicit, finely resolved microstructure in a critical region while resolving the smoother mechanical fields outside this region with a coarser discretization to limit computational cost. The microstructural physics is modeled with a high-fidelity model that incorporates anisotropic crystal elasticity and rate-dependent crystal plasticity to simulate the behavior of a stainless steel alloy. The component-scale material behavior is treated with a lower fidelity model incorporating isotropic linear elasticity and rate-independent J2 plasticity. The microstructural and component scale subdomains are modeled concurrently, with coupling via the Schwarz alternating method, which solves boundary-value problems in each subdomain separately and transfers solution information between subdomains via Dirichlet boundary conditions. In this study, the framework is applied to model incipient localization in tensile specimens during necking.

Alleman, Coleman A.; Foulk, James W.; Karlson, Kyle N.; Manktelow, Kevin M.; Ostien, Jakob O.; Stender, Michael S.; Stershic, Andrew J.; Veilleux, Michael V.

Abstract not provided.

Computer Methods in Applied Mechanics and Engineering

Mota, Alejandro M.; tezaur, tezaur; Alleman, Coleman A.

This corrigendum clarifies the conditions under which the proof of convergence of Theorem 1 from the original article is valid. We erroneously stated as one of the conditions for the Schwarz alternating method to converge that the energy functional be strictly convex for the solid mechanics problem. Finally, we have relaxed that assumption and changed the corresponding parts of the text. None of the results or other parts of the original article are affected.

Nguyen, Phi N.; Alleman, Coleman A.; Stender, Michael S.

Abstract not provided.

Owen, Steven J.; Foulk, James W.; Reedlunn, Benjamin R.; Ernst, Corey D.; Alleman, Coleman A.; Lim, Hojun L.

Abstract not provided.

Foulk, James W.; Alleman, Coleman A.; Mota, Alejandro M.; Lim, Hojun L.; Littlewood, David J.; Bergel, Guy L.; Popova, Evdokia P.; Montes de Oca Zapiain, David M.

The heterogeneity in mechanical fields introduced by microstructure plays a critical role in the localization of deformation. To resolve this incipient stage of failure, it is therefore necessary to incorporate microstructure with sufficient resolution. On the other hand, computational limitations make it infeasible to represent the microstructure in the entire domain at the component scale. In this study, the authors demonstrate the use of concurrent multi- scale modeling to incorporate explicit, finely resolved microstructure in a critical region while resolving the smoother mechanical fields outside this region with a coarser discretization to limit computational cost. The microstructural physics is modeled with a high-fidelity model that incorporates anisotropic crystal elasticity and rate-dependent crystal plasticity to simulate the behavior of a stainless steel alloy. The component-scale material behavior is treated with a lower fidelity model incorporating isotropic linear elasticity and rate-independent J 2 plas- ticity. The microstructural and component scale subdomains are modeled concurrently, with coupling via the Schwarz alternating method, which solves boundary-value problems in each subdomain separately and transfers solution information between subdomains via Dirichlet boundary conditions. Beyond cases studies in concurrent multiscale, we explore progress in crystal plastic- ity through modular designs, solution methodologies, model verification, and extensions to Sierra/SM and manycore applications. Advances in conformal microstructures having both hexahedral and tetrahedral workflows in Sculpt and Cubit are highlighted. A structure-property case study in two-phase metallic composites applies the Materials Knowledge System to local metrics for void evolution. Discussion includes lessons learned, future work, and a summary of funded efforts and proposed work. Finally, an appendix illustrates the need for two-way coupling through a single degree of freedom.

Littlewood, David J.; Alleman, Coleman A.; Bergel, Guy L.; Foulk, James W.; Mota, Alejandro M.; Lim, Hojun L.

Abstract not provided.