Prediction of miscibility in chlorinated polyethylene/poly(vinyl chloride) blends via atomistic molecular dynamics simulations

ZH Ma and X Li and HG Xu and JX Shen and J Liu, RSC ADVANCES, 16, 916-930 (2025).

DOI: 10.1039/d5ra09560c

The miscibility of chlorinated polyethylene (CPE)/polyvinyl chloride (PVC) blends is intricately influenced by both chemical structures and environmental conditions. This study employs all-atom molecular dynamics simulations to systematically investigate the effects of CPE chlorine content and molecular architecture, blend composition, and temperature on CPE/PVC miscibility behavior. Analysis of solubility parameters (delta) suggests that the compatibility of CPE/PVC blends improves with increasing chlorine content within the examined range. Random- chlorinated polyethylene (r-CPE) demonstrates superior miscibility with PVC compared to block-chlorinated polyethylene (b-CPE), attributed to enhanced electrostatic contributions arising from intensified polar Cl- Cl interactions. CPE/PVC blends containing approximately 20-80 wt% CPE are found to be thermodynamically immiscible at 300 K. Furthermore, a quantitative relationship between the Flory-Huggins interaction parameter (chi 12) and temperature (T) is established, revealing an increase in chi 12 with T, indicative of reduced miscibility at higher temperatures. The phase diagram exhibits a low critical solution temperature (LCST) behavior, consistent with the chi 12-T relationships. Notably, r-CPE/PVC binary systems exhibit a higher LCST critical temperature (Tcr) than b-CPE/PVC systems. In general, this simulation study provides better understandings of CPE/PVC miscibility and offers valuable guidance for the design and optimization of CPE/PVC composite materials.

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