Research on supercapacitor has focu

Research on supercapacitor has focused on the development of electrode active materials, such as high surface area carbon having pores adapted to the size of ions, conducting polymers, and tran-sition metal oxides (TMOs) [4e7]. Of which, TMOs such as RuO2$H2O, MnO2, SnO2, NiOH, and Co 2O3 are proposed as possible electrode materials due to their higher specific capacitance. These TMOs are associated with faradic redox reactions in cyclic vol-tammograms (CVs) and plateaus in galvanostatic chargeedischarge curves. Contrarily, RuO2$H2O and MnO2 electrodes show non-faradaic features such as rectangular forms in CVs and straight lines in galvanostatic chargeedischarge curves [8e11]. However, the high cost and toxicity of RuO2$H2O limits its practical applications. Therefore, MnO2 is one of the most promising electrodes for ECs because of its low cost, abundance, and environmentally benign nature [12e15].

Generally, electrolytes functions well in neutral aqueous elec-trolytes such as Na2SO4, Li2SO4, K2SO4, and KCl. However, RuO2$H2O and NiOH can be used only in a strong acidic or alkaline electrolyte [8,16]. The review indicates that only 30% of the theoretical-specific capacitance (~1400 F g 1) value of MnO2 is obtained experimentally [17e19]. To improve the performance, it is necessary to design new MnO2 materials with a complete knowledge on the properties of charge storage mechanism as an electrode. The electrode active materials at their nanoscale particle size show uniform morphology with high surface area results in good electrochemical performance [20,21]. The recent studies on nanoparticle electrode active mate-rials show the dependence of specific capacitance and power/en-ergy density on their textural properties such as morphology, surface area, pore size, and pore volume [22e24]. Extensive research on increasing the surface area of MnO2 are conducted to improve the electrochemical performance with different synthesis techniques such as solegel [25], sonochemical [26], hydrothermal [27], combustion [28], microemulsion [29], soft template [30] and electrochemical methods [31]. Among these, sonochemical and soft template methods are widely used as a useful technique for the synthesis of porous MnO2 nanoparticles [26,30].


Research on supercapacitor has focused on the development of electrode active materials, such as high surface area carbon having pores adapted to the size of ions, conducting polymers, and tran-sition metal oxides (TMOs) [4e7].