Regulating the Coordination of Co sites in Co3 O4 /MnO2 Compounding for Facilitated Oxygen Reduction Reaction

Engineering Co2+ Coordination in α-Co(OH)2 and its Conversion to Co3O4 Nanoparticles for Application in Asymmetric Supercapacitors

Owing to their unique redox behaviour and structural versatility, cobalt hydroxide/cobalt oxide-based nanomaterials have emerged as promising materials for energy storage. However, the interrelation between coordination environment of Co2+ and its effect on their electrochemical behaviour remains unexplored. α-Co(OH)₂ contains Co2+ in octahedral coordination (Co2+ Oh). However, careful engineering of Co2+ coordination to tetrahedral (Co2+ Td) can significantly affect the supercapacitive performance. Herein, a simple homogeneous precipitation method is used to achieve this transformation. At low concentration of Co salt (5 mmol), pink-coloured α-Co(OH)₂ nanoflakes (Co(OH)₂-PP) are formed with only Co2+ Oh, whereas at higher concentration of cobalt salt (50 mmol), blue colored α-Co(OH)₂ nanorods (Co(OH)₂-BP) are formed with both Co2+ Oh and Co2+ Td. The maximum specific capacity reached 167.5 C g-1 for Co(OH)₂-BP which showed ~200 % increment as compared to α-Co(OH)₂-PP at 10 mV s-1. The enhancement results from favourable transformation of Co2+ Td to electroactive Co3+ in CoOOH, high surface area (99 m2 g-1) and small crystallite size (23.5 nm) of Co(OH)₂-BP. α-Co(OH)₂ was thermally decomposed to obtain Co3O4 nanoparticles. The specific capacity of Co₃O₄ nanoparticles derived from Co(OH)₂-BP and Co(OH)₂-PP are 136.3 C g-1 and 110.7 C g-1, respectively, the fomer showing only a marginal increase in specific capacity. An asymmetric supercapacitor device based on Co(OH)₂-BP//rGO exhibits peak energy density of 14.6 W h kg-1 and peak power density of ~12 kW kg-1. The insights from this study will significantly impact the development of advanced energy storage materials.