Manifestation of the Enhanced Photovoltaic Performance in Eco-Friendly AgBiS<sub>2</sub> Solar Cells Using Titanium Oxynitride as the Electron Transport Layer
S. Akhil, Mithun Prakash Ravikumar, Mohammed Jalalah, Mabkhoot Alsaiari, Farid A. Harraz, Sakar Mohan, R. Geetha Balakrishna
Abstract
In this study, titanium oxynitride with empirical composition of TiON is developed using a sol–gel and ammonia-gas-assisted thermal nitridation process. The obtained TiON phase is employed as the photoanodic electron transport layer (ETL) in a silver bismuth sulfide (AgBiS2) quantum-dot-sensitized solar cell (QDSSC) device and compared to a QDSSC consisting of commercial TiO2 as the ETL. The obtained X-ray photoelectron spectroscopy spectra and Mott–Schottky plots of the samples suggested that the valence and conduction bands of TiON are significantly shifted (EVB = 2.9 eV and ECB = −0.3 eV) with respect to that of TiO2 (EVB = 1.88 eV and ECB = −0.51 eV), which eventually decreased its band gap energy to 2.46 eV compared to TiO2 (3.2 eV). A decrease in the charge transfer resistance (Rct = 38.2 Ω) and improvement in carrier lifetime (τ = 5.3 ms) are observed in the developed TiON device. The work also endorses the use of eco-friendly green quantum dots of AgBiS2 as photoabsorbers in solar cells. Although the photovoltaic performance is not found to be greater, the demonstration of the enhanced performance of the TiON-based device with ∼50% enhancements, owing to its improved open circuit voltage and current density by 20 and 35%, is achieved in this work. Titanium oxynitride can, hence, be considered a suitable alternative to existing commercial TiO2 in all applications that involve solar energy conversion.