Hierarchical Activated Carbon Fibers as a Sustainable Electrode and Natural Seawater as a Sustainable Electrolyte for High-Performance Supercapacitor
Abstract
This study demonstrates a facile, cost-effective, green, and sustainable fabrication of supercapacitor devices using high surface area (2350 m2 g−1) activated carbon fibers as supercapacitor electrode. The electrochemical behavior of the supercapacitor electrodes with different neutral electrolytes such as LiCl, KCl, and NaCl is carefully investigated and compared with natural seawater as an economic and sustainable electrolyte for the first time. The maximum specific capacitance of carbon fibers electrode in different electrolytes is around 101 Fg−1 in LiCl, 134 Fg−1 in KCl, 159 Fg−1 in NaCl, and 172 Fg−1 in natural seawater at a current density of 1 Ag−1. Surprisingly, the seawater-based supercapacitor exhibits a very good durability upon 10 000 charge–discharge cycles with 99% of capacitance retention and 99% of coulombic efficiency. For practical validity, integrated solar cell–based supercapacitor pouch cells are investigated. The seawater is explored as an eco-friendly, cost-effective, and alternative aqueous electrolyte, which may replace the existing aqueous-based electrolytes for the fabrication of an economic and green supercapacitor device.
Conflict of Interest
The authors declare no conflict of interest.
