Effects of chemical composition, mild alkaline pretreatment and particle size on mechanical, thermal, and structural properties of binderless lignocellulosic biopolymers prepared by hot-pressing raw microfibrillated Phoenix dactylifera and Cocos nucifera fibers and leaves

We developed value-added, high-strength lignocellulosic biopolymers by exploiting high-lignin biomass waste of palms. Lignocellulosic biopolymers were prepared by hot-pressing microfibrillated raw and alkaline pre-treated date and coconut fibers and leaves powders consisting of (<= 53-<= 106 mu m) particles in the range 140-180 degrees C. The obtained biopolymers were subjected to three-point bending strength, water resistance, structural morphology (SEM), thermal stability (TGA/DTG), spectroscopy (FTIR), and crystallinity (XRD) analyses. Findings showed that raw fiber-based and alkaline-pretreated biopolymers exhibited bending strength, water resistance, and thermal stability (similar to 200 degrees C) superior to those of leaf-based biopolymers. Furthermore, lignocellulosic biopolymers prepared from smaller particles showed enhanced bending and thermal properties, compared to those prepared from large particles. By mechanical and thermal properties, the optimum results were observed for biopolymers pre-treated with 1 wt% NaOH, except for coconut leaf-based biopolymers. Results were correlated to chemical composition and particle size of milled lignocellulosic biomass, allowing for efficient lignin condensation.