Characterization of manufacturing material and carbon nanohybrid for renewable energy and storage systems

Abstract

Scientists are exploring advanced energy alternatives to compete with rising fossil fuel consumption and CO2 emissions due to population growth and technological advancements. Supercapacitors are highly efficient systems for storing energy due to their specific capacitance and power density, meeting modern energy storage demands. Perovskite and carbon-based materials have emerged as the most effective materials in this respect. In this work, SrSnO3/rGO nanohybrid is chosen as the supercapacitor electrode material for the very first time and a range of characterization techniques are employed to ascertain the structural and textural characteristics of the composite. The physicochemical properties of the SrSnO3 included rGO are shown to have a greater surface area, excellent electrical conductivity and a lower resistance. It is demonstrated that the rGO improved quicker ion diffusion channels for the increased redox performance in the SrSnO3/rGO nanohybrid. Additionally at 1 A/g, the SrSnO3/rGO nanohybrid has an elevated specific capacitance of 1385 F/g along with energy and power density of 66 Wh/kg and 293 W/kg, respectively in a three-electrode system. During the two electrode observations, the revealed Cs of SrSnO3/rGO nanohybrid was 122 F/g at 1 A/g with 66 Wh/kg and 293 W/kg of energy density and power density, respectively. The SrSnO3/rGO nanohybrid has exceptional functionality, as demonstrated by its 65 h stability examination via chronoamperometry and a modest drop in its CV polarization curve area after the 5000th cycle of the CV stability analysis. These evaluated results point to the nanohybrid's promising future.