Abstract
This study reports the performance analysis of an organic dye-sensitized solar cell (DSSC), introducing MnO2 as an electron transport layer in TiO2/MnO2 bilayer assembly. The DSSCs have been fabricated using TiO2 and TiO2/MnO2 layer-by-layer architecture films onto fluorine-doped tin oxide (FTO) glass and sensitized with natural dye extracted from Malvaviscus penduliflorus flower in ethanol medium. The counter electrode was prepared to layer copper powder containing paste onto FTO's conductive side by the doctor's blade method. The optical, morphological, and structural properties of photoanodes were explored via ultraviolet–visible, field emission scanning electron microscopy, and X-ray diffraction analyses. Moreover, dye complexity and thermostability of dyes were characterized via Fourier-transform infrared spectroscopy and thermogravimetric analyses. The iodide/triiodide (i.e., I−/I3−) redox couple of electrolyte solution was employed as a charge transport medium between the electrodes. Finally, photoanode and counter electrode sandwiches were assembled to envisage the photovoltaic performance potential under simulated AM 1.5G solar illumination using 100 mW cm–2 light intensity. The as-fabricated DSSC comprising TiO2/MnO2 bilayer assembly exhibited 6.02 mA cm–2 short circuit current density (Jsc), 0.38 V open-circuit voltage (Voc), 40.38% fill factor, and 0.92% conversion efficiency, which is about 200% higher compared to the assembly devoid of MnO2 layer.
Highlights
Nowadays, clean, near-zero-emission and sustainable renewable energy production are vital concerns for policymakers worldwide
Natural dye extract from Malvaviscus penduliflorus flower has been used for the fabrication of low-cost and ecofriendly dye-sensitized solar cell (DSSC)
The Fourier-transform infrared spectroscopy (FTIR) result indicates the interaction of dye molecule with alcohol
Summary
Clean, near-zero-emission and sustainable renewable energy production are vital concerns for policymakers worldwide. The energy consumption demand is expected to be doubled in 2050 [1, 2]. A significant percentage of energy demand is backed by fossil fuel-based resources, implying an adverse impact on global warming, environment, and ecosystem. The DSSC module works as a photoelectrochemical device in which electron–hole pair is generated via light-induced exciton [3]. The sensitizer mostly influences the performance potential of DSSC. The natural color pigments of plant leaves, fruits, and flowers can be used as a sensitizer for DSSC application(s). Though DSSC has impressive performance under indoor lighting, the long-term stability and outdoor performance under high-temperature ambient conditions are yet to be achieved to date [6]. The DSSC conversion efficiency is much lower than that
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