Efficient non-fullerene organic solar cells employing aqueous solution-processed MoO3as a hole-transporting layer.

Organic solar cell (OSC) has drawn considerable interest in recent decades owing to their advantages of light weight, flexible, large area and potentially low-cost. Employing an appropriate hole-transporting layer (HTL) into an OSC device has been proved as an efficient method to obtain high efficiency OSC due to the enhancement of the hole transporting and extraction of the device. In this work, aqueous solution-processed MoO3(s-MoO3) thin films were employed as HTLs to construct non-fullerene PM6:Y6 OSCs. The s-MoO3thin film was prepared by using an aqueous solution process from an isopolymolybdate [NH4]6Mo7O24.4H2O precursor followed by thermal annealing treatment to convert the precursor to MoO3. The s-MoO3HTL based PM6:Y6 device demonstrates a power conversion efficiency of 15.75%, which is 38% improved than that of the device with thermally evaporated-MoO3as HTL and 8% improved than that of the device with PEDOT:PSS as HTL. The enhancement of the device performance could be attributed to the enhanced hole mobility and better band matching of the s-MoO3HTL. Moreover, the s-MoO3HTL based PM6:Y6 device exhibited higher device stability than those of the reference devices. Our finding indicates that this s-MoO3film has great potential as efficient HTL for high performance non fullerene OSCs.

Cloning and expression of a novel thermostable cellulase from newly isolated Bacillus subtilis strain I15.

A novel bacterial strain with high cellulase activity (2.82 U/ml) was isolated, and then identified by its morphological character and 16S rRNA sequence, and named Bacillus subtilis strain I15. The extracellular thermostable cellulase exhibited the maximum activity at 60 degrees C and pH 6.0. It was very stable since more than 90% of original CMCase activity was maintained at 65 degrees C after incubation for 2 h. The cellulase gene, celI15, was cloned and extracellularly expressed by Escherichia coli BL21 (DE3), which encoded the extracellular protein of about 52 kDa. The extracellular activity of CelI15 from E. coli BL21 was up to about 6.78 U/ml, and all the other properties were almost the same as that from the wild-type strain.