Synthesis and characterization of binary transition metal oxides and polyaniline nanocomposite

Abstract

Innovative nanocomposite materials with enhanced electrochemical abilities have a wide range of applications in the field of materials science. Synthesizing high performing nanocomposites with low-cost simple methods, characterizing and investigating them for their electrochemical properties shall find suitable applications particularly in energy storage. The electrochemical advantages of nanorange materials with improved porosity, surface area and active sites and the composite combination of binary metal oxides and conducting polymer with synergistic advantage shall provide excellent scope for application in the field of energy storage. The role of energy storage devices is indispensable in the global scenario of exhausting energy reserves and energy-centric technological advancements of humankind. Supercapacitors are the best appreciated, advanced energy storage technology, with promising deliverance of exceptional power density, fast charge-discharge process, lasting cycle life, firm thermal range and other features. By overcoming the limitations of batteries by high power density and ordinary capacitors by high energy density, supercapactitors are a forefront technology in energy storage. Researches are focused on investigating innovative electrode materials with enriched electrochemical efficiency for high performance of the supercapacitor. The central focus of this work is to achieve innovative and efficient nanocomposite materials by simple, time saving and low cost commercially viable synthesizing methods, characterized and investigated for relevant application in energy storage, particularly supercapacitors. Transition Metal oxides and conducting polymers have been widely experimented using electrode materials in pseudocapacitors newline