AI Article Synopsis
- Marine fouling challenges the performance and lifespan of marine engineering equipment, making effective antifouling coatings essential for economic, environmental, and safety considerations in offshore operations.
- This study developed an innovative, environmentally friendly antifouling coating using lignin, which is renewable, biodegradable, and reduces the need for petroleum-based materials, improving water contact angle and hydrophobicity by 14.5%.
- The lignin-based coating demonstrated a 200% increase in mechanical strength and an 85% reduction in friction coefficient, enhancing durability and preventing organism adhesion, thereby promoting greener antifouling solutions in marine engineering.
Article Abstract
Marine fouling poses significant challenges to the efficiency and longevity of marine engineering equipment. To address this issue, developing effective marine antifouling coatings is critical to ensure the economic viability, environmental sustainability, and safety of offshore operations. In this study, we developed an innovative green antifouling and wear-resistant coating based on lignin, a renewable and sustainable resource. Lignin is considered environmentally friendly because it is abundant, biodegradable, and reduces reliance on petroleum-based materials. The coating was formulated with a controlled hydrophilic-to-hydrophobic ratio of 2:8, leveraging lignin's unique properties. Applying lignin increased the water contact angle by 14.5 %, improving surface hydrophobicity and contributing to the coating's antifouling efficacy. Moreover, the mechanical strength of the coating was enhanced by approximately 200 %, significantly boosting its durability in harsh marine environments. Additionally, the friction coefficient was reduced by about 85 %, further preventing organism adhesion. These results demonstrate that lignin-based coatings offer a greener alternative to traditional antifouling solutions. The results of this study not only help advance antifouling coating technology but are also consistent with the broader goal of promoting environmental responsibility in marine engineering practice.
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| http://dx.doi.org/10.1016/j.ijbiomac.2024.137456 | DOI Listing |
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