Seawater Effects on Thermally Aged Ambient Cured Carbon/Epoxy Composites: Moisture Kinetics and Uptake Characteristics

• Published in: Polymers Vol. 15; no. 9; p. 2138
• Main Authors: Karbhari, Vistasp M., Acharya, Rabina, Hong, SoonKook
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 29.04.2023; MDPI
• Subjects: Aging; Analysis; Carbon; Carbon fiber reinforced plastics; Carbon-epoxy composites; Curing; Design; Electrolytes; Epoxy matrix composites; Epoxy resins; Fiber composites; Fiber reinforced polymers; High temperature; Hydrogen bonds; Kinetics; Moisture effects; Polymers; Sea-water; Seawater; Submerging; Transition points; United States; United Kingdom; diffusion; thermal aging; deterioration; seawater; relaxation; carbon/epoxy composite; hygrothermal
• ISSN: 2073-4360; 2073-4360
• DOI: 10.3390/polym15092138

Carbon fiber-reinforced epoxy matrix composites using ambient- and moderate-temperature curing non-autoclave processes have broad applicability in marine, offshore, and naval applications. This research focuses on the characterization of moisture kinetics of ambient cured carbon/epoxy composites subject to immersion in seawater for up to 72 weeks after prior periods of extended thermal aging. A two-stage model is shown to best describe the overall kinetics and response. The level of maximum moisture uptake shows an increasing trend with the temperature and time of prior thermal aging, reaching asymptotic levels at the highest levels. The transition point is seen to represent a shift between the diffusion and relaxation-/deterioration-based dominant regimes, and the ratio of uptake at the transition point to the maximum uptake can be correlated to the relaxation coefficient. Diffusivity, as expected, generally increases with the temperature of prior aging and shows changes based on the level of post-curing and network changes with time. Moisture uptake kinetics and characteristics developed through the sequence of exposures provide a better understanding of phenomena towards the development of a future comprehensive model capable of long-term prediction based on the sequential prior history of exposure to elevated temperatures and immersion in seawater.