TY - JOUR
T1 - The derivation of CRSS in pure Ti and Ti-Al alloys
AU - You, Daegun
AU - Celebi, Orcun Koray
AU - Mohammed, Ahmed Sameer Khan
AU - Bucsek, Ashley
AU - Sehitoglu, Huseyin
N1 - The work is supported by the DOE-Basic Energy Sciences (Dr.J.Vetrano, PD), under Award Number DE-SC0023008, which is gratefully acknowledged. In addition, the use of the Illinois Campus Cluster, a computing resource that is operated by the Illinois Campus Cluster Program (ICCP) in conjunction with the National Center for Supercomputing Applications (NCSA) and which is supported by funds from the University of Illinois at Urbana-Champaign, is also gratefully acknowledged.
PY - 2025/1
Y1 - 2025/1
N2 - The work focuses on the determination of the critical resolved shear stress (CRSS) in titanium (Ti) and titanium-aluminum (Ti-Al) alloys, influenced by an array of factors such as non-symmetric fault energies and minimum energy paths, dislocation core-widths, short-range order (SRO) effects which alter the local atomic environment, and tension-compression (T-C) asymmetry affected by intermittent slip motion. To address these multifaceted complexities, an advanced theory has been developed, offering an in-depth understanding of the mechanisms underlying slip behavior. The active slip systems in these materials are basal, prismatic, and pyramidal planes, with the latter involving both 〈a〉 and 〈c+a〉 dislocations. Each slip system is characterized by distinct Wigner-Seitz cell configurations for misfit energy calculations, varying partial dislocation separation distances, and unique dislocation trajectories—all critical to precise CRSS calculations. The theoretical CRSS results were validated against a comprehensive range of experimental data, demonstrating a strong agreement and underscoring the model's efficacy.
AB - The work focuses on the determination of the critical resolved shear stress (CRSS) in titanium (Ti) and titanium-aluminum (Ti-Al) alloys, influenced by an array of factors such as non-symmetric fault energies and minimum energy paths, dislocation core-widths, short-range order (SRO) effects which alter the local atomic environment, and tension-compression (T-C) asymmetry affected by intermittent slip motion. To address these multifaceted complexities, an advanced theory has been developed, offering an in-depth understanding of the mechanisms underlying slip behavior. The active slip systems in these materials are basal, prismatic, and pyramidal planes, with the latter involving both 〈a〉 and 〈c+a〉 dislocations. Each slip system is characterized by distinct Wigner-Seitz cell configurations for misfit energy calculations, varying partial dislocation separation distances, and unique dislocation trajectories—all critical to precise CRSS calculations. The theoretical CRSS results were validated against a comprehensive range of experimental data, demonstrating a strong agreement and underscoring the model's efficacy.
KW - Critical stress
KW - Dislocations
KW - Short-range order
KW - Stacking fault
KW - Titanium
KW - Wigner-Seitz cell
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U2 - 10.1016/j.ijplas.2024.104187
DO - 10.1016/j.ijplas.2024.104187
M3 - Article
AN - SCOPUS:85211051698
SN - 0749-6419
VL - 184
JO - International journal of plasticity
JF - International journal of plasticity
M1 - 104187
ER -