Potassium-doped organometal halide perovskite solar cells (PSCs) of more than 20% power conversion efficiency (PCE) without I-V hysteresis were constructed. The crystal lattice of the organometal halide perovskite was expanded with increasing of the potassium ratio, where both absorption and photoluminescence spectra shifted to the longer wavelength, suggesting that the optical band gap decreased. In the case of the perovskite with the 5% K+, the conduction band minimum (CBM) became similar to the CBM level of the TiO2-Li. In this situation, the electron transfer barrier at the interface between TiO2-Li and the perovskite was minimised. In fact, the transient current rise at the maximum power voltages of PSCs with 5% K+ was faster than that without K+. It is concluded that stagnation-less carrier transportation could minimise the I-V hysteresis of PSCs.
The improvement of solar cell performance
in the near-infrared
(near-IR) region is an important challenge to increase power conversion
efficiency under one-sun illumination. PbS quantum-dot (QD)-based
heterojunction solar cells with high efficiency in the near-IR region
were constructed by combining ZnO nanowire arrays with PbS QDs, which
give a first exciton absorption band centering at wavelengths longer
than 1 μm. The morphology of ZnO nanowire arrays was systematically
investigated to achieve high light-harvesting efficiency as well as
efficient carrier collection. The solar cells with the PbS QD/ZnO
nanowire structures made up of densely grown thin ZnO nanowires about
1.2 μm long yielded a maximum incident-photon-to-current conversion
efficiency (IPCE) of 58% in the near-IR region (@1020 nm) and over
80% in the visible region (shorter than 670 nm). The power conversion
efficiency obtained on the solar cell reached about 6.0% under simulated
one-sun illumination.
For improvement of solar cell performance, it is important to make efficient use of near-infrared light, which accounts for ∼40% of sunlight energy. Here we introduce plasmonic Ag nanocubes (NCs) to colloidal PbS quantum dot/ZnO nanowire (PbS QD/ZnO NW) bulk-heterojunction solar cells, which are characterized by high photocurrents, for further improvement in the photocurrent and power conversion efficiency (PCE) in the visible and near-infrared regions. The Ag NCs exhibit strong far field scattering and intense optical near field in the wavelength region where light absorption of PbS QDs is relatively weak. Photocurrents of the solar cells are enhanced by the Ag NCs particularly in the range 700-1200 nm because of plasmonic enhancement of light absorption and possible facilitation of exciton dissociation. As a result of the optimization of the position and amount of Ag NCs, the PCE of PbS QD/ZnO NW bulk-heterojunction solar cells is improved from 4.45% to 6.03% by 1.36 times.
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