Epoxy resin thermo-mechanics and failure modes: Effects of cure and cross-linker length
SC Chowdhury and RM Elder and TW Sirk and JW Gillespie, COMPOSITES PART B-ENGINEERING, 186, 107814 (2020).
DOI: 10.1016/j.compositesb.2020.107814
The effects of molecular weight (MW) of cross-linker and degree of cure on the structure and thermo-mechanical properties of the Bisphenol A diglycidyl ether epoxy resin have been studied using MD simulations with reactive force field ReaxFF and non-reactive General AMBER Force Field (GAFF). Cross-linked structures are created from stoichiometric mixtures of Epon and Jeffamine (R) using a multi-step cross-linking algorithm. The glass transition temperature (T-g) is determined by annealing where the cross-linked epoxy is cooled from the rubbery state to below room temperature. Deformation mechanisms of the cross-linked epoxy including bond breakage are studied under tensile and shear loadings. The effects of cross-linkers of increasing MW (Jeffamine (R) D-230, Jeffamine (R) D-400 and Jeffamine (R) D-600) are studied for highly cured (98.5% degree of cure) systems. MD predicted T-g is in good agreement with experiments after cooling rate correction using the WLF relationship. The highest T-g is obtained for the lower MW cross-linker that exhibits a denser network structure. In addition, the effects of varying degrees of cure on properties are studied for Epoxy/Jeffamine (R) D-230. In this case, the MD results shows that T-g increases linearly with degree of cure and that the DiBenedetto relationship can be applied using the MD fitted parameters. Lower MW cross-linker yields higher modulus and yield stress and reduced strain to failure and energy absorption than the higher MW cross-linkers. Results from GAFF, which is about 100 times more computationally efficient, agree well with ReaxFF predictions up to the strain limit at which bond breakage becomes significant.
Return to Publications page