Article ID Journal Published Year Pages File Type
184586 Electrochimica Acta 2015 7 Pages PDF
Abstract

•As an upconverter, lanthanide-doped NaYF4 has been integrated into the photoanodes for quantum-dot sensitized solar cells to widen the solar light harvesting range.•The upconverter based solar cells exhibit an obvious increase in the photocurrent generation and the power conversion efficiency.•Annealing-induced upconversion enhancement could further improve the solar cell performance.

As an upconverter, lanthanide-doped NaYF4 (Ln-NaYF4) has been integrated into the photoanodes for quantum-dot sensitized solar cells. Compared with the solar cells with pure TiO2, the upconverter based solar cells exhibited a 17.6% increase in the photocurrent and a 20% increase in the power conversion efficiency. Furthermore, when the integrated Ln-NaYF4 is pretreated by annealing, the resulting photoanode demonstrates an obvious improvement in the photocurrent generation and the power conversion efficiency due to the annealing-induced enhancement of the upconversion emission as well as the elimination of the defects allowing for efficiently reducing charge recombination. The best photovoltaic performance with a short-circuit current of 14.36 mA/cm2 and a power conversion efficiency of 4.37% has been obtained with the solar cells containing the annealed upconverters. Both the solar cells integrated with the Ln-NaYF4 pretreated by annealing or not demonstrate obvious photocurrent responses under the illumination of the NIR light. This finding demonstrates the feasibility of the combination of the up-converting materials with quantum dot-sensitized solar cells to extend the exploitation of the solar light to a wider range thus enabling the fabrication of highly efficient solar cells.

Graphical abstractUpconverters have been integrated into the photoanodes of quantum dot-sensitized solar cells to widen the utilization range of solar light through the upconversion process. The QDSSCs with upconverters demonstrate an enhanced photovoltaic performance with a short-circuit current of 14.36 mA/cm2 and a power conversion efficiency of 4.37%.Figure optionsDownload full-size imageDownload as PowerPoint slide

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Physical Sciences and Engineering Chemical Engineering Chemical Engineering (General)
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