Optimization of nano cellulose extraction from timoho fiber using response surface methodology (RSM)

“…Table 2 elucidates the distinctive properties of the synthesized SNPC in comparison to diverse lignocellulosic biomasses. Interestingly, this study achieved a higher cellulose yield of 82 % from jack fruit peduncle [ 9 ], 45 % from red banana empty fruit bunches [ 15 ], 65–70 % from millet husk [ 83 ], 78 % from Cuscuta reflexa [ 84 ], 94.83 % from Sunn hemp [ 85 ], 89.39 % from Agave gigantea [ 86 ], 65 % from sugarcane bagasses [ 87 ], 23.54 % from rice husk [ 88 ] and 84.75 % from timoho fiber [ 89 ], respectively. This result highlights the feasibility and effectiveness of this approach as implemented on a larger scale.…”

Innovative ionic liquid pretreatment followed by wet disk milling treatment provides enhanced properties of sugar palm nano-fibrillated cellulose

“…Table 2 elucidates the distinctive properties of the synthesized SNPC in comparison to diverse lignocellulosic biomasses. Interestingly, this study achieved a higher cellulose yield of 82 % from jack fruit peduncle [ 9 ], 45 % from red banana empty fruit bunches [ 15 ], 65–70 % from millet husk [ 83 ], 78 % from Cuscuta reflexa [ 84 ], 94.83 % from Sunn hemp [ 85 ], 89.39 % from Agave gigantea [ 86 ], 65 % from sugarcane bagasses [ 87 ], 23.54 % from rice husk [ 88 ] and 84.75 % from timoho fiber [ 89 ], respectively. This result highlights the feasibility and effectiveness of this approach as implemented on a larger scale.…”

Innovative ionic liquid pretreatment followed by wet disk milling treatment provides enhanced properties of sugar palm nano-fibrillated cellulose

Extraction of pure cellulose from palm residues using alkaline treatment method and its performance in PVC polymer matrix composite

Mechanical, wear, and flammability properties of silanized cow dung biosilica-dispersed corn husk Fiber-reinforced epoxy composites