Electrochemical Studies of Inkjet Printed Semi-Transparent NiCo2O4/ITO Supercapacitor Electrodes

Transparent supercapacitors find a large number of applications as components of many electronic devices and circuits. Mixed Ni-Co oxides (NCOs) are among the most promising supercapacitor electrode materials exhibiting high pseudo-capacitance and good electronic conductivity, while inkjet printing is a low cost and versatile technique for electrode printing. Surprisingly, although there have been many studies of NCO supercapacitor films on ITO glass substrates, these have not been prepared by the inkjet technique, and their optical properties were not fully characterized. Hereby, we report the fabrication and characterization of thin (295 and 477 nm thick; 0.017 and 0.035 mg cm(-2) NCO loading) semi-transparent NiCo2O4/ITO supercapacitor electrodes, showing transparency to visible light (60-30%, from the thinner to the thicker electrode layers tested), typical mass specific capacitance for NCO-based supercapacitor electrodes (1294-829 Fg(-1) at 1 mA cm(-2) discharge current density) and high volumetric capacitance (746-608 F cm(-3) at 1 mA cm(-2)). The NCO nanoparticles were prepared by hydrothermal synthesis followed by thermal treatment and ball milling (ZrO2 balls, 0.5 mm diameter), resulting in a cubic nickel-cobalt oxide structure and particle size in the 30-150 nm range, whereas the electrode layers were printed from water-propylene glycol solutions using a Dimatix DMP-2850 drop-on-demand (DoD) inkjet printer. Constant current charge-discharge experiments of the supercapacitor electrode (at ca 0.5 mA cm(-2)) for 1000 cycles confirmed stability of performance.

Automated summary

Transparent supercapacitors are widely used in electronic devices and circuits. Ni-Co oxides (NCOs) as electrode materials for supercapacitors show high pseudo-capacitance and good electronic conductivity. This study reports the fabrication and characterization of thin semi-transparent NiCo2O4/ITO supercapacitor electrodes, which exhibit transparency to visible light and high capacitance. The NCO nanoparticles were prepared by hydrothermal synthesis followed by thermal treatment and ball milling, while the electrode layers were printed using an inkjet printer. The stability of the supercapacitor electrode's performance was confirmed through constant current charge-discharge experiments.