Chain Ends and the Ultimate Strength of Polyethylene Fibers
TC O'Connor and MO Robbins, ACS MACRO LETTERS, 5, 263-267 (2016).
DOI: 10.1021/acsmacrolett.5b00838
We use large scale molecular dynamics (MD) simulations to determine the tensile yield mechanism of orthorhombic polyethylene (PE) crystals with finite chains spanning 10(2)-10(4) carbons in length. We find the yield stress sigma(gamma) saturates for long chains at 6.3 GPa, agreeing well with experiments. We show chains do not break, but always yield by slip, after nucleation of 1D dislocations at chain ends. Dislocations are accurately described by a Frenkel-Kontorova model parametrized by the mechanical properties of an ideal crystal. We compute a dislocation core size xi approximate to 25 angstrom and determine the high and low strain rate limits of sigma(gamma) Our results suggest characterizing the 1D dislocations of polymer crystals as an efficient method for numerically predicting the ultimate tensile strength of aligned fibers.
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