Abstract
The performance of quantum dot-sensitized solar cell (QDSSC) is mainly limited by chemical reactions at the interface of the counter electrode. Generally, the fill factor (FF) of QDSSCs is very low because of large charge transfer resistance at the interface between the counter electrode and electrolyte solution containing redox couples. In the present research, we demonstrate the improvement of the resistance by optimization of surface area and amount of catalyst of the counter electrode. A facile chemical synthesis was used to fabricate a composite counter electrode consisting of fluorine-doped tin oxide (FTO) powder and CuS nanoparticles. The introduction of a sputtered gold layer at the interface of the porous-FTO layer and underlying glass substrate also markedly reduced the resistance of the counter electrode. As a result, we could reduce the charge transfer resistance and the series resistance, which were 2.5 [Ω] and 6.0 [Ω], respectively. This solar cell device, which was fabricated with the presently designed porous-FTO counter electrode as the cathode and a PbS-modified electrode as the photoanode, exhibited a FF of 58%, which is the highest among PbS-based QDSSCs reported to date.
Highlights
The first quantum dot-sensitized solar cell (QDSSC) was reported over two decades ago [1]
All X-ray diffraction meter (XRD) diffraction peaks of the fluorine-doped tin oxide (FTO) powder were assigned to rutile SnO2 (ICDD number 01-076-7837, space group: P42/mnm)
We investigated the XRD pattern for CuS powder synthesized by the same starting solution of the successive ionic layer adsorption and reaction (SILAR) method, and all diffraction peaks were assigned to covellite CuS crystal phase
Summary
The first quantum dot-sensitized solar cell (QDSSC) was reported over two decades ago [1]. The high energy conversion efficiencies of QDSSC have been reported for PbS [3, 4] quantum dots (QD) and CdSexTe1−x QD [5] with ZnS shell. These QDSSCs exhibited higher short circuit current (Jsc) than a DSSC due to their absorption of a wider range of visible light and higher quantum yield. The low Voc and insufficient FF of QDSSCs limit their energy conversion efficiency of solar cells [8]
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