Development of nitrogen and phosphorus dual-doped reduced graphene oxide from waste plastic for supercapacitor applications: Comparative electrochemical performance in different electrolytes
Kundan Singh Rawat, Chetna Tewari, Tanuja Arya, Young Nam Kim, Prabhat Pant, Satish Chandra Sati, Sunil Dhali, Pushpa Bhakuni Negi, Yong Chae Jung, Nanda Gopal Sahoo
Abstract
The persistent non-biodegradable nature of plastic highlights the urgent need for effective waste management and resource conservation, underscoring the crucial importance of recycling and upcycling within a cradle-to-cradle framework. This research introduces an eco-friendly and straightforward upcycling process for plastic waste, which produces significant quantities of reduced graphene oxide through a carefully designed 2-stage pyrolysis method. To enhance the electrochemical properties of the reduced graphene oxide, they were doped with heteroatoms (i.e. nitrogen and phosphorus) via a hydrothermal route. Also, as the nature of the electrolyte plays a significant role in electrochemical analysis, a comparative evaluation of the supercapacitive performance of the heteroatom-doped reduced graphene oxide was conducted across various aqueous electrolytes, including 1 M H 2 SO 4 , 6 M KOH, and 2 M KCl, as well as hydrogel polymer electrolytes such as 1 M H 2 SO 4 /1 M PVA, 2 M KCl/1 M PVA, and 6 M KOH/1 M PVA. Our results demonstrate that synthesized material from waste plastic exhibits excellent performance, particularly when combined with a 1 M H 2 SO 4 electrolyte, achieving the highest specific capacitance of 407.6 F/g. In conclusion, this study presents a cost-effective and sustainable approach to promoting a circular economy by repurposing waste plastic for energy storage applications. • Development of N & P Dual-Doped Graphene Nanosheets from waste plastics. • Comparative evaluation of supercapacitive performance across various electrolytes. • Reducing plastic pollution while advancing energy storage technology. • Promoting circular economy for sustainable energy storage.