Highly stable electrodeposited 2D Mn0.2Co0.8 LDH nanoplatelets based symmetric supercapacitor electrode

High performance Mn0.2Co0.8 layered double hydroxide (LDH)-based binder free supercapacitor symmetric electrode is fabricated via single step electrochemical deposition. The synthesized Mn0.2Co0.8 electrode shows specific capacitance of 370.58-141.17 F/g (315-120 C/g) at 2-40 A/g within potential range - 0.45-0.4 V along with 172.72% capacitance retention for 9000 GCD cycles. Additionally, a symmetric supercapacitor is also made utilizing Mn0.2Co0.8 LDH both as cathode and anode. The high potential of synthesized electrode as a supercapacitor material is shown by achieving a specific capacitance of 106.91-34.57 F/g at 0.5-3 A/g within a cell voltage of 0 to 0.8 V, as well as outstanding cyclic stability over 5000 GCD cycles. Red LEDs are used to analyze the real world application of the fabricated symmetric supercapacitor for energy storage and it is assumed that the future portable electrical systems and gadgets might benefit from the device based on the reported material and synthesis technique.

Automated summary

A high performing Mn0.2Co0.8 layered double hydroxide (LDH)-based binder-free supercapacitor symmetric electrode was fabricated using a single-step electrochemical deposition. The synthesized electrode showed specific capacitance of 370.58-141.17 F/g (315-120 C/g) and retained 172.72% capacitance after 9000 GCD cycles. A symmetric supercapacitor was also prepared using the Mn0.2Co0.8 LDH as both cathode and anode, exhibiting specific capacitance of 106.91-34.57 F/g and excellent cyclic stability over 5000 GCD cycles.