posted on 2019-11-01, 14:38authored bySubodh
C. Tiwari, Kohei Shimamura, Ankit Mishra, Fuyuki Shimojo, Aiichiro Nakano, Rajiv K. Kalia, Priya Vashishta, Paulo S. Branicio
Ab initio molecular dynamics simulations of shock
loading on poly(p-phenylene terephthalamide) (PPTA)
reveal stress release mechanisms based on hydrogen bond preserving
structural phase transformation (SPT) and planar amorphization. The
SPT is triggered by [100] shock-induced coplanarity of phenylene groups
and rearrangement of sheet stacking leading to a novel monoclinic
phase. Planar amorphization is generated by [010] shock-induced scission
of hydrogen bonds leading to disruption of polymer sheets, and trans-to-cis conformational change of polymer
chains. In contrast to the latter, the former mechanism preserves
the hydrogen bonding and cohesiveness of polymer chains in the identified
novel crystalline phase preserving the strength of PPTA. The interplay
between hydrogen bond preserving (SPT) and nonpreserving (planar amorphization)
shock release mechanisms is critical to understanding the shock performance
of aramid fibers.