Iridium-palladium binary alloy as a counter electrode in dye-sensitized solar cells

This study is concerned with the iridium-palladium (Ir-Pd) binary alloy as a counter electrode (CE) for DSSC. The CE was prepared using the liquid phase deposition (LPD) technique. The influence of the concentration of hydrogen hexachloroiridate(iv) hydrate (H2Cl6Ir center dot H2O) on the properties and the performance of the device was investigated. The source of iridium was H2Cl6Ir center dot H2O. XRD analysis confirmed that the dominant phase of Ir-Pd existed in the sample. The grain size of Ir-Pd increased with the increase in the concentration of H2Cl6Ir center dot H2O until an optimum concentration of 0.7 mM was reached. The % wt of Ir was found to increase with the concentration of H2Cl6Ir center dot H2O. The device utilizing Ir-Pd CE with 0.7 mM H2Cl6Ir center dot H2O demonstrated the highest power conversion efficiency (PCE) of 5.84%, beating that of the device with Pt CE having a PCE of 5.04%. This is because the device possesses the lowest charge transfer resistance (Rct), highest recombination resistance (Rcr), and longest carrier lifetime (tau), and the device possesses the highest reduction current (Jpc) and incident-photon conversion efficiency (IPCE). The PCE was significantly affected by Ir content in the binary alloy of Ir-Pd. According to the PCE result, Ir-Pd CE was found as a suitable substitution for Pt as CE for the device. This study is concerned with the iridium-palladium (Ir-Pd) binary alloy as a counter electrode (CE) for DSSC.

Automated summary

This study focuses on the use of iridium-palladium (Ir-Pd) binary alloy as a counter electrode (CE) for dye-sensitized solar cells (DSSC). By adjusting the concentration of hydrogen hexachloroiridate (IV) hydrate (H2Cl6Ir·H2O), the property and performance of the CE were investigated. The device with Ir-Pd CE containing 0.7 mM H2Cl6Ir·H2O demonstrated the highest power conversion efficiency (PCE) compared to the device with platinum (Pt) CE.