Developing biodegradable materials, particularly biodegradable composites, has gained significant attention due to the increasing awareness of environmental impacts and the need for sustainable alternatives. These composites, made from natural fibers and polymers, are renewable, recyclable, and compostable, offering several advantages over traditional materials. Natural lignocellulosic fibers (NLFs) such as sisal, flax, and hemp are favored for their availability, cost-effectiveness, lightweight nature, and good mechanical properties. Green composites, which use biodegradable polymers as the matrix, show promise but require further research to understand their reinforcing mechanisms fully. Cellulose nanofibers (CNFs) and biobased epoxy resins, like vanillin-based epoxies, are being explored for their high strength, stiffness, and thermal stability. Hybrid composites combining cotton gin waste (CGW) with flax fibers have improved mechanical properties, making CGW a viable option for reinforcing polylactic acid (PLA). Despite these advancements, issues such as poor compatibility with common polymers and the need for efficient lignin extraction and purification processes remain. The potential for biodegradable composites to replace traditional materials in various applications, including construction, automotive, and medical devices, is significant, but further research is needed to overcome current limitations and expand their applications.

Sustainable; Green composite; Biodegradable

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