Molten-state cubic cage-templated uniform C3N4 hollow nanocubes and improved electrochemical performance of asymmetric micro-supercapacitor

“…As previously stated, the synthesis conditions considerably influence the structure and hence electrochemical properties of the synthesized graphitic carbon nitride as indicated in the Table 3 [56][57][58][59][60][61][62] . Thus, the nature of starting precursors and the mode of synthesis of the graphitic carbon nitride is very crucial to apprehending its electrochemical output compared to other nanocarbon varieties.…”

“…Furthermore, in many cases, the similarity in electronic structures have been an additional advantage for nanocomposite formation with smoother interface, as in case of graphene and graphitic carbon nitride, for enhancing the supercapacitor performance relative to the bare components. For instance, g-C 3 N 4 @graphene composite exhibited an overall 75% increment in capacitance attributed to introduction of graphitic carbon nitride to graphene system owing to the reduced aggregation of graphene sheets thereby enhancing the capacity retention efficacy during charging/discharging cyclic performances of the composite [60] .…”

Graphitic Carbon Nitride (g-C3N4): A Proficient Electrode Material for Flexible Supercapacitors

“…As previously stated, the synthesis conditions considerably influence the structure and hence electrochemical properties of the synthesized graphitic carbon nitride as indicated in the Table 3 [56][57][58][59][60][61][62] . Thus, the nature of starting precursors and the mode of synthesis of the graphitic carbon nitride is very crucial to apprehending its electrochemical output compared to other nanocarbon varieties.…”

“…Furthermore, in many cases, the similarity in electronic structures have been an additional advantage for nanocomposite formation with smoother interface, as in case of graphene and graphitic carbon nitride, for enhancing the supercapacitor performance relative to the bare components. For instance, g-C 3 N 4 @graphene composite exhibited an overall 75% increment in capacitance attributed to introduction of graphitic carbon nitride to graphene system owing to the reduced aggregation of graphene sheets thereby enhancing the capacity retention efficacy during charging/discharging cyclic performances of the composite [60] .…”

Graphitic Carbon Nitride (g-C3N4): A Proficient Electrode Material for Flexible Supercapacitors

“…Despite significant progresses have been achieved in device structures, integrated systems, and preparation methods, there are no reviews focused on various types of electrode materials for MSCs. In addition, although some reviews involved electrode materials, 23 they only focused on a particular class, such as graphite-based materials, 24 flexible materials, 25 or highly cross-linked porous polymers. Therefore, there is still a great need for a comprehensive review in time to introduce the latest developments in electrode materials for MSCs and compare their advantages and disadvantages, applicability, and scalable preparation methods.…”

Recent progress in electrode materials for micro-supercapacitors

In the Construction of Energy Storage Supercapacitors, Nanostructures Play a Key Role