The relationship between oxidation and hydrolysis in the conversion of cellulose in NaVO sub(3)-H sub(2)SO sub(4) aqueous solution with O sub(2)

Conversion of cellulose, the most abundant biomass, shows a high selectivity to yield formic acid (FA), when oxidized by O sub(2) in NaVO sub(3)-H sub(2)SO sub(4) aqueous solution. This conversion involves various reactions including hydrolysis and oxidation. In this work, the relationships between these reactions were studied. There are mainly two hydrolyses and two oxidations occurring in the conversion: initial hydrolysis (from cellulose to monosaccharides) and deep hydrolysis (from monosaccharides to levulinic acid); catalytic oxidation (from monosaccharides to FA) and ordinary oxidation (from levulinic acid to acetic acid). Among these four reactions, catalytic oxidation to FA and deep hydrolysis to byproducts are competitive. The increasing rate of deep hydrolysis is faster than that of catalytic oxidation, when temperature is increased. Catalytic oxidation is promoted and deep hydrolysis is suppressed, when the O sub(2) pressure is increased. Moreover, deep hydrolysis is promoted and catalytic oxidation is suppressed, when H sub(2)SO sub(4) concentration is increased. The hydrolysis-oxidation pathway of this conversion was proposed. Thus, the byproducts could be inhibited, and FA-oriented transformation could be realized.