📝 SummarXiv

Abstract

High-density polyethylene (HDPE) thin films, while inherently ductile, exhibit poor flaw tolerance. Our experiments show that they fail prematurely not at the point of maximum stretch, but at the boundary of a necked region or notch-tip plastic zone. This study investigates this counter-intuitive failure mechanism and demonstrates how an elastomeric interlayer can mitigate it to enhance toughness. Through a combined experimental (uniaxial, center-notched, pure shear tests) and computational approach, we analyze freestanding HDPE and HDPE-SEPS-HDPE trilayer laminates. Finite element simulations reveal that failure in free-standing HDPE is not governed by a maximum stretch criterion. Instead, it is driven by ductile damage, modeled using a damage parameter that depends on stress-triaxiality and plastic strain. This damage localizes initially at the notch or neck center, but migrates into a "hotspot" at the neck/plastic zone boundary, matching the observed crack initiation site. The addition of a soft SEPS interlayer fundamentally alters this behavior by suppressing the ductile damage, causing the failure mechanism to switch from being damage-driven at the neck/plastic zone boundary to being stretch-driven at the notch tip. This switch enhances flaw tolerance and stretchability by relocating and delaying fracture initiation in both defect-free and notched geometries. This work exposes the failure mechanism in HDPE thin films and provides a mechanistically-grounded framework for toughening ductile polymers by manipulating the competition between damage and stretch localization.