Researchers from China's Beihang University and Changchun University of Technology have developed a new surface engineering strategy to build low-cost solar cells without a hole transport layer. The devices were treated with benzoylcholine halide to reduce non-radiation recombination and achieved impressive efficiency and stability.
The research group developed a carbon-based all-inorganic perovskite solar cell without the use of an expensive hole transport layer (HTL). In the proposed cell architecture, the absence of the HTL, which prevents direct contact between the carbon electrode and the perovskite, is compensated by engineering the surface composition of the perovskite film. ”The bipolar transport of the perovskite layer and the hole extraction ability of the carbon electrode provide a theoretical basis for the preparation of HTL-free CsPbI2Br carbon-based all-inorganic perovskite solar cells,” the researchers said in their study.
The team explained that chemical reactions can be used to modify the low-dimensional (LD) structure on a three-dimensional (3D) perovskite surface to improve the crystallization quality. They used, in particular, benzoylcholine halide (BzChX), which they said “effectively” passivates halogen vacancy defects on the film, while reducing non-radiation recombination.
“At the same time, an LD/3D heterostructure is formed on the surface of the CsPbI2Br perovskite films modified by BzChI and BzChBr, which promote the gradient energy level arrangement between the perovskite films and carbon electrode,” they stated.
The team designed the cell with a substrate made of tin oxide (FTO), an electron transport layer made of titanium oxide (TiO2), an absorber made of a CsPbI3 perovskite material and a carbon electrode.
Tested under standard illumination condition, the proposed cell achieved a power conversion efficiency of 14.15%, an open-circuit voltage of 1.21 V, and a fill factor of 79.03%. For comparison, a reference cell without the benzoylcholine halide treatment achieved an efficiency of 12.29%, an open-circuit voltage of 1.20 V, and a fill factor of 78.36%. The scientists also found that the cells treated with benzoylcholine halide, after 120 s steady-state output, still retained over 92.9% of their initial efficiency.
“This work provides a feasible way to achieve concurrent energy level optimization and defect passivation by constructing an LD/3D heterostructure for high-performance CsPbI2Br-based photovoltaics,” the team stated.
