초록
<P><B>Abstract</B></P> <P>Cassava starch is an abundant feedstock for biological transformation to ethanol, however, its industrial processing needs further improvements to enhance efficiency and cost-effectiveness. In the present study, a low-cost catalyst (CC–SO<SUB>3</SUB>H) was synthesized by partial carbonization and sulfonation of crystalline cellulose, which was thermally stable and reactive at 160°C in 5 times repeated batch of thermohydrolysis of cassava starch. The catalyst was studied for its potential role in the hydrolysis of cassava starch as a standard feedstock. It was shown that the milling of cassava starch in the presence of the CC–SO<SUB>3</SUB>H catalyst improved the solid-state reaction that enhanced porosity, increased surface area and decreased crystallinity of the starch granules. These phenomena caused the rapid thermohydrolysis of starch with an exceptionally high starch conversion rate (96.43%), glucose yield (93.12%), and glucose selectivity (95.32%) within 2h of reaction at 160°C, 10bar. The highest ethanol yield (0.43g ethanol/g total reducing sugars) was achieved at 96h of fermentation corresponding to the highest ethanol concentration of 15.41g/L from the fermentation of hydrolysate of mixed-milling/thermo-hydrolysis at 160°C for 2h of cassava starch. In addition, the reaction kinetics showed the feasibility of this process for robust bioethanol production from starchy feedstocks.</P> <P><B>Highlights</B></P> <P> <UL> <LI> A cellulose-based low-cost, thermostable, recyclable catalyst was synthesized. </LI> <LI> The impact of catalyst was studied on the bioprocessing of cassava starch to glucose. </LI> <LI> Catalytic mixed-milling/thermohydrolysis provides highest starch conversion. </LI> <LI> The bioprocessing optimization improves ethanol fermentation of cassava starch. </LI> </UL> </P>