<i>Ab initio</i> shock loading on poly (p-phenylene terephthalamide) (PPTA) and its implications for Kevlar and other aramid-based fibers performance
ORAL
Abstract
Ab initio molecular dynamics simulations using the multi-scale shock technique are applied in the study of the dynamic response of poly (p-phenylene terephthalamide) (PPTA) crystals to shock loading. PPTA crystals form the bulk of para-aramid fibers, such as Kevlar and Twaron, and are responsible for their outstanding strength-to-weight ratio. Strong shock loadings describe the shock response from elastic to polymer decomposition. Results reveal an anisotropic response for shocks perpendicular to the crystal symmetry axis (aramid fiber axis) including stress release mechanisms combining structural phase transformation (SPT) and production of paracrystallinity. SPT is observed for shocks along the [100] direction and are triggered by shock-induced coplanarity of amide and phenylene groups resulting in reorganization of PPTA sheet stacking. Generation of paracrystallinity is triggered by [010] shock-induced scission of hydrogen bonds, trans-cis polymer conformation change, and disruption of chain sheets. While the SPT preserves crystalline order and PPTA properties the generation of paracrystallinity strongly affects PPTA strength. The simulation results provide an atomistic view on the effects of shock in para-aramid fibers.
*ARL subcontract # 259411-USC to Temple University.
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Presenters
Paulo Branicio
University of Southern California
Authors
Paulo Branicio
University of Southern California
Subodh Tiwari
University of Southern California
Univ of Southern California
Kohei Shimamura
University of Southern California
Fuyuki Shimojo
Physics, Kumamoto University
Kumamoto University
Department of Physics, Kumamoto University
Aiichiro Nakano
Univ of Southern California
Physics & Astronomy, University of Southern California
University of Southern California
Mork Family Department of Chemical Engineering and Materials Science, Univ of Southern California
Collaboratory of Advanced Computing and Simulations, Univ of Southern California
Physics, University of Southern California
Rajiv Kalia
Univ of Southern California
Physics & Astronomy, University of Southern California
University of Southern California
Mork Family Department of Chemical Engineering and Materials Science, Univ of Southern California
Collaboratory of Advanced Computing and Simulations, Univ of Southern California
Collaboratory for Advanced Computing and Simulations, University of Southern California
Physics, University of Southern California
Priya Vashishta
Univ of Southern California
Physics & Astronomy, University of Southern California
University of Southern California
Mork Family Department of Chemical Engineering and Materials Science, Univ of Southern California
Collaboratory of Advanced Computing and Simulations, Univ of Southern California
Collaboratory for Advanced Computing and Simulations, University of Southern California
