a comprehensive review of the multidimensional nanostructural properties of graphene carbon nitride as a supercapacitor electrode

This abstract offers a comprehensive review of recent advancements in graphene carbon nitride (gcn) as a highly promising electrode material for supercapacitors. gcn boasts exceptional advantages, including abundant availability, a metal-free composition, high nitrogen content, and remarkable environmental sensitivity. these unique characteristics have positioned gcn at the forefront of research in energy storage and supercapacitor electrode materials. however, despite its potential, gcn faces challenges concerningin terms of limited specific capacity and energy density. to address these limitations, this review, article as the first and most comprehensive in its field,review article focuses on innovative and novel development methods, particularly the strategic formation of nanostructures in 1, 2, and 3 dimensions. aone notable finding of this review is the tremendous promise of 3d structures in enhancingelevating the electrochemical properties of gcn as a supercapacitor electrode. a criticalacritical research gap in other review articles is the absence of comprehensive and innovative literature (investigating nanostructures (1d, 2d, and 3d) with novelnovelty synthesis methods for) on using gcn as a supercapacitor electrode. this underscores the pressing need for further scholarly investigation in this area, as addressed by like this review article. overall, this professional review article not only provides a comprehensive overview of the advancements in gcn as a supercapacitor electrode material but also offers valuable guidance for researchers in the field. it highlightssuch as the importanceutilization of utilizing environmentally friendly synthesis techniques for fabricatingthe fabrication of multidimensional nanostructures, illuminating. it illuminates novel research directions and highlights pioneering investigations. this empowers, empowering researchers to further advance the utilization of gcn in energy storage applications.