Wang F, Wang J, Chen Z, Liu X, Xiao L, Jiang L, Qu B, Wang S, Gong Q.
In Situ Synthesis of Poly(copper phthalocyanine) Nanostructures for Organic Nanodevices. CHEMISTRY LETTERS. 2014;43:1040-1042.
Men J, Ting H, Li Y, Wang W, Gao G, Xiao L, Chen Z, Wang S, Gong Q.
Static and ultrafast time-resolved fluorescent anisotropy in oriented Poly(3-hexylthiophene) films. CHEMICAL PHYSICS LETTERS. 2014;609:33-36.
Men J, Ting H, Li Y, Wang W, Gao G, Xiao L, Chen Z, Wang S, Gong Q.
Static and ultrafast time-resolved fluorescent anisotropy in oriented Poly(3-hexylthiophene) films. CHEMICAL PHYSICS LETTERS. 2014;609:33-36.
Ma Y, Zheng L, Chung Y-H, Chu S, Xiao L, Chen Z, Wang S, Qu B, Gong Q, Wu Z, et al. A highly efficient mesoscopic solar cell based on CH3NH3PbI3-xClx fabricated via sequential solution deposition. CHEMICAL COMMUNICATIONS. 2014;50:12458-12461.
Zheng L, Chung Y-H, Ma Y, Zhang L, Xiao L, Chen Z, Wang S, Qu B, Gong Q.
A hydrophobic hole transporting oligothiophene for planar perovskite solar cells with improved stability. CHEMICAL COMMUNICATIONS. 2014;50:11196-11199.
Zheng L, Chung Y-H, Ma Y, Zhang L, Xiao L, Chen Z, Wang S, Qu B, Gong Q.
A hydrophobic hole transporting oligothiophene for planar perovskite solar cells with improved stability. CHEMICAL COMMUNICATIONS. 2014;50:11196-11199.
Ma Y, Zheng L, Chung Y-H, Chu S, Xiao L, Chen Z, Wang S, Qu B, Gong Q, Wu Z, et al. A highly efficient mesoscopic solar cell based on CH3NH3PbI3-xClx fabricated via sequential solution deposition. CHEMICAL COMMUNICATIONS. 2014;50:12458-12461.
Zheng L, Ma Y, Chu S, Wang S, Qu B, Xiao L, Chen Z, Gong Q, Wu Z, Hou X.
Improved light absorption and charge transport for perovskite solar cells with rough interfaces by sequential deposition. NANOSCALE. 2014;6:8171-8176.
AbstractRecently, highly efficient solar cells based on organic-inorganic perovskites have been intensively reported for developing fabricating methods and device structures. Additional power conversion efficiency should be gained without increasing the thickness and the complexity of the devices to accord with practical applications. In this paper, a rough interface between perovskite and HTM was fabricated in perovskite solar cells to enhance the light scattering effect and improve the charge transport. The parameters related to the morphology have been systematically investigated by sequential deposition. Simultaneous enhancements of short-circuit current and power conversion efficiency were observed in both CH3NH3PbI3 and CH3NH3PbI3-xClx devices containing the rough interface, with power conversion efficiencies of 10.2% and 10.8%, respectively. Our finding provides an efficient and universal way to control the morphology and further optimize perovskite solar cells for devices by sequential deposition with various structures.