In-situ nano-engineering of amorphous MoS2 nanosheets with carbon dots for enhanced supercapacitor performances

Amorphous materials have snatched special attention for electrochemical energy storage applications owing to the presence of plenty of activate sites for energy storage. Herein, we report the microwave-assisted-hydrothermal synthesis of amorphous MoS2 with some 1T phase and in-situ-nano-engineering with C-dots for energy storage application. The specific capacitance (C-s) of a-MoS2/C-dots was found to be 1368 F g(-1) (at 1 A g(-1)), which is similar to 2.9 and 1.65 times higher than a-MoS2 (without C-dots) and crystalline c-MoS2/C-dots. Capacitance is also strongly dependent on synthesis methods: C-s of a-MoS2/C-dots is 2.15 times higher than h-MoS2/C-dots produced by the normal-hydrothermal method. The asymmetric supercapacitor was designed using a-MoS2/C-dots as cathode and activated-carbon as anode showing C-s 180.82 F g(-1) at a maximum potential of 1.5 V. Energy density (ED) of 56.5 W h kg(-1) at a power density (PD) of 750 W kg(-1) with excellent capacitance retention was observed. The high C-s of a-MoS2/C-dots can be attributed to amorphous MoS2, formation of metallic 1T phase, good charge transport, and strong catalyst support interaction. This synthesis and in-situ nano engineering method of MoS2 may provide a promising technique for developing a high-performance supercapacitor for energy storage applications.

Automated summary

The microwave-assisted-hydrothermal synthesis of amorphous MoS2 with in-situ nano-engineered C-dots for energy storage applications shows significantly higher specific capacitance compared to other synthesis methods. The high capacitance can be attributed to the amorphous nature of MoS2, formation of metallic 1T phase, good charge transport, and strong catalyst support interaction, providing a promising technique for developing high-performance supercapacitors.