We can't find the internet
Attempting to reconnect
Something went wrong!
Hang in there while we get back on track
Influence of Green Nanofillers on the Morphological, Mechanical Properties, and Degradation Kinetics of <scp>PBS</scp>/<scp>PBAT</scp> Blends: A Potential Sustainable Strategy for Fisheries Applications
Summary
Researchers developed biodegradable polymer blends reinforced with nanochitin and nanocellulose — materials derived from natural sources — as a potential replacement for synthetic nylon fishing nets. The bio-based nanofillers improved the mechanical strength and altered degradation rates of the PBS/PBAT blends, bringing performance closer to what is needed for real fishing applications. Replacing synthetic nylon with biodegradable alternatives could meaningfully reduce ghost fishing and the microplastic pollution that comes from fragmenting nets in the ocean.
ABSTRACT Synthetic nylon fishing nets pose significant threats to marine ecosystems, contributing to ghost fishing and microplastic pollution. While the development of biodegradable polymers for marine applications has progressed, significant challenges remain in achieving the mechanical performance required for fishing nets, particularly under water conditions. This study addresses these challenges by investigating the incorporation of nanochitin and nanocellulose fillers into PBS/PBAT blends, aiming to optimize their mechanical properties and to control the degradation behavior for marine environments. First, various PBS/PBAT nanocomposites were prepared with chitin and cellulose nanofillers, and tensile tests identified the most effective fillers for mechanical reinforcement. Differential scanning calorimetry (DSC), size exclusion chromatography (SEC), and scanning electron microscopy (SEM). The results demonstrated significant mechanical reinforcement in air conditions, with efficient nanofiller dispersion, particularly in two nanocomposites: PBS/PBAT/ChNCsLac 1% and PBS/PBAT/NFCEster 1% . These formulations exhibited notable improvements in mechanical properties compared to the other blends. Specifically, Young's modulus increased by +15% and + 22%, respectively, while elongation at break improved by +10% and + 7%, respectively. Under aqueous conditions, PBS/PBAT/ChNCsLac 1% also showed a remarkable +52% increase in elongation at break. Additionally, weathering tests were also examined the nanofillers' influence on degradation kinetics, revealing that chitin nanofillers accelerated degradation under controlled conditions. These findings suggest that while nanochitins and nanocelluloses improve mechanical properties in certain environments, further research is required to optimize their performance in water.
Sign in to start a discussion.