Supercapacitors (SCs) have been widely explored as emerging, electrochemically clean, and green energy storage devices. Metal oxides have been focused as promising SC electrode materials due to their excel-lent electrochemical, chemical and physical properties. With rapid progress in this area, mixed bimetallic oxides as well as mixed trimetallic oxides have also been explored. In a comparison, trimetallic/ternary-metal oxide-based nanostructure materials are highly desired for overcoming the limitation of poor elec-tronic conductivity of single and bimetallic oxides. Owing to the presence of multiple oxidation states and synergistic effect, such mixed metal oxides offer high specific capacitance/capacity, excellent cy-cle life, and high energy density. The current review article summarizes the structure, properties, and electrochemical performance of the trimetallic/ternary-metal oxides-based nanostructures for SC appli-cations. For the electrochemical evaluation of these electrodes, many basic fundamental misinterpreta-tion/misconception arises over the past few years. To clarify such misconceptions, the misinterpretation in thermal terminologies; charge storage mechanism in capacitive-, pseudocapacitive-, and battery-type electrode materials; symmetric, asymmetric, and hybrid devices; and the equations used for different cal-culations in energy storage devices have been clarified and discussed systematically in the second part of this review article. Finally, the future outlook of the SC applications of such trimetallic/ternary-metal oxides has been addressed.

• Institution
  兰州大学