Research

Leveraging state-of-the-art synthesis technologies, our research focuses on tailoring the optical and electronic properties of nanomaterials and their heterostructures to enhance device functionalities. Key applications encompass large area broadband photodetectors, biosensors, corrosion inhibitors, photo-electrochemical water splitting, and supercapacitors. Through meticulous manipulation at the nanoscale, our approach enables precise tuning of material characteristics, facilitating optimized device performance. This multidisciplinary endeavor integrates expertise from materials science, nanotechnology, and device engineering to pioneer innovative solutions for pressing societal and technological demands. Our findings underscore the transformative potential of nanotechnology in driving advancements across various sectors, from renewable energy to healthcare and environmental sustainability. Through a state-of-the-art synthesis process devised in our laboratory, we engineer size and morphology-tunable nano-heterostructures tailored for multifunctional purposes. These nanostructures exhibit versatile properties suitable for optoelectronic, electrochemical applications, antimicrobial activities, and supercapacitors. Our approach enables precise control over material characteristics, facilitating optimized performance in various energy harvesting applications. Through this endeavor, we aim to contribute to the advancement of sustainable energy technologies and multifunctional materials with broad-reaching societal benefits.