Bioaugmentation of Corn Stalks Saccharification with Aspergillus Fumigatus Under Low/High Solid Loading Culture

Decomposed the dense structure of lignocellulosic feedstocks and hydrolysis lignocellulose into monosaccharide were essential prerequisite for bio-energy production at this level. In this study, a cellulosic fungi Aspergillus fumigatus CLL was conducted to pretreated the corn stalks under high/low solid loading culture to enhanced the cellulase saccharification performance. The results indicated that A. fumigatus CLL decomposed the corn stalks effectively under high/low solid loading culture, what’s more, A. fumigatus CLL completed the T. reesei cellulase system and promoted the corn stalks saccharification performance. 25.2% lignin was degraded after A. fumigatus CLL treated just for two day under low solid loading culture with holocellulose loss less than 10%. Meanwhile, the β-glucosidase of A. fumigatus CLL complemented the incomplete cellulase system of T. reesei, the maximum saccharification ratio of sample saccharified by T. reesei cellulase combined A. fumigatus CLL was comparable with the sample saccharified by commercial cellulase. Compared with raw corn stalks, the saccharification ratio of pretreated sample increased 3.1-3.4 fold. These results demonstrated that A. fumigatus CLL can be used for pretreatment of lignocellulosic materials to enhanced the saccharification performance.

Digital Light Processing 3D Printing of Surface-oxidized Si3N4 Coated by Silane Coupling Agent

Due to high light absorption and high refractive index of silicon nitride (Si3N4) ceramic, it is difficult to prepare Si3N4 slurry with favourable curing ability, high solid loading and low viscosity at the same time, and thus the high quality Si3N4 parts are hard to fabricate via Digital Light Processing (DLP). In this paper, oxidation process was used to enhance the curing behavior of Si3N4 slurry, and then silane coupling agent (KH560) was used to improve the rheological properties of the oxidized Si3N4 slurry. The effect of Si3N4 slurry with oxidation and modification on its rheological behavior, light absorption, curing ability and stability have been systematically investigated. A Si3N4 slurry with abundant photocuring ability, high solid loading, low viscosity and reliable stability was fabricated by the oxidized (1h) and KH560 (1wt.%) modified Si3N4 powders, and the dense Si3N4 ceramic parts were produced by this slurry via DLP 3D printing. Subsequently, the influence of oxidation and modification on microstructure, mechanical properties and thermal conductivity have been investigated. Finally, the performances of the DLP 3D printed samples are close to the isostatic cool pressing (ICP) fabricated samples. Consequently, DLP has well potential to fabricate high-performance Si3N4 ceramics.