Lignocellulosic reinforced composites: a snapshot of progress
Amal H. Abdel Kader, Tamer Y. A. Fahmy, Samir Kamel
Abstract
Lignocellulosic fiber-reinforced composites have emerged as a sustainable alternative to synthetic composites, offering renewable, low-cost, and eco-friendly solutions for diverse industrial applications. This review highlights recent advancements in utilizing lignocellulosic fibers across matrices such as thermoplastics, thermosets, rubber, cement, gypsum, and ceramics, emphasizing their transformative potential in achieving a circular economy. Key innovations include advanced surface modification techniques, such as nanocellulose reinforcement and bio-based coupling agents, which significantly enhance mechanical properties, thermal stability, and durability. The integration of nanocellulose derived from agricultural waste has demonstrated remarkable improvements in tensile strength and crack resistance, enabling high-performance, lightweight composites. The review also explores the role of circular economy principles, with a focus on recycling and upcycling lignocellulosic waste into valuable materials. Innovations like 3D-printed composites and lignin-based modifiers underscore the potential for reducing the carbon footprint of composite production. Emerging applications in additive manufacturing and multifunctional composites, such as fire-retardant and electrically conductive materials, further highlight the versatility of lignocellulosic fibers in addressing modern engineering challenges. Despite challenges related to scalability, moisture sensitivity, and thermal stability, advancements in chemical treatments, hybrid systems, and bio-based matrices provide a solid foundation for future research. This review consolidates the state of the art in lignocellulosic fiber-reinforced composites, showcasing their pivotal role in sustainable material development and inspiring continued innovation for a greener future.