Exploration of structural, thermal stability and band-gap tunability of organic and inorganic mixed cation (MA)1-xCsxPbBr3perovskite harvester via ultrasonication synthesis route.
Rajan Kumar SinghKhalid Bin MasoodNeha JainRadha TamrakarJai SinghRanveer KumarPublished in: Journal of physics. Condensed matter : an Institute of Physics journal (2021)
Extensive investigation over the last few years has been done on halide based perovskite light harvester due to higher power conversion efficiency but the thermal stability with organic cation i.e. methylamine is challenging for the commercialization. Therefore, for improved structural and thermal stability, it is significant to develop a mixed cation base perovskite compound. To improve the thermal and structural stability of the material and easy synthesis method for industrialization of the material, we have demonstrated the compositional engineering of MA/CsPbBr3perovskite material via ultrasonication synthesis process. The x-ray diffraction, transmission electron microscope, diffuse reflectance spectrometer and simultaneous thermal analyzer (STA) analysis were performed in order to understand the impact of the Cs+into MAPbBr3perovskite structure. Structural study reveals that up to 40% Cs+incorporation into MAPbBr3has purePm-3mcubic phase of perovskite compound with continuously increase in micro strain and lattice contraction. On the other hand, with increasing the concentration of Cs+than MA+, optical band gap slightly increases. The thermodynamic behavior and thermal stability of the sample was studied with STA (differential scanning calorimetry/thermogravimetry). For the new generation optoelectronics with admirable stability, we believe that pure phase MA0.60Cs0.40PbBr3perovskite compound may be a promising candidate.