Separation of Lignocellulose and Preparation of Xylose from Miscanthus lutarioriparius with a Formic Acid Method

Abstract: Efficient component separation technology is one of the key ways to improve the efficiency of lignocellulose bioconversion. In this study, the formic acid method was used to separate the components of lignocellulose from Miscanthus Lutarioriparius, hemicellulose was degraded into xylose simultaneously, and the composition and structure of the separated components were analyzed. Then, xylose was further purified with activated carbon for decolorization and resins for the removal of formic acid and other monosac… Show more

“…Cellulose, cellulose microfibers and paper [ 57 , 58 , 59 , 60 ], cellulose nanocrystals [ 61 ], oligosaccharides [ 62 , 63 , 64 , 65 ] and xylene [ 30 ] are derived from miscanthus. Pidlisnyuk et al [ 66 ] comprehensively reviewed some products from miscanthus (agricultural products, insulation and composite materials, hemicelluloses, pulp and paper).…”

Recent Advances in Miscanthus Macromolecule Conversion: A Brief Overview

“…Cellulose, cellulose microfibers and paper [ 57 , 58 , 59 , 60 ], cellulose nanocrystals [ 61 ], oligosaccharides [ 62 , 63 , 64 , 65 ] and xylene [ 30 ] are derived from miscanthus. Pidlisnyuk et al [ 66 ] comprehensively reviewed some products from miscanthus (agricultural products, insulation and composite materials, hemicelluloses, pulp and paper).…”

Recent Advances in Miscanthus Macromolecule Conversion: A Brief Overview

Lignocellulose reconstituted shape-controllable self-supporting carbonaceous capacitance-anodes with high electron transfer rates for high-performance microbial electrochemical system

Promotion of lignin depolymerization and cellulose utilization via the coupling effects of DDQ pre-oxidation and HCOOH extraction