Different from an ideal rectangular shape of the typical electrical double-layer capacitance, the redox reaction peaks indicate that the capacitance mainly results from the pseudocapacitive capacitance [24]. The pseudocapacitance arises from the reaction between the Mn4+ ions and NaOH electrolyte [25, 26]. The peak current increases when the scan rate increases from 5 to 20 mV · s–1, while the anodic peaks shift toward the positive potential and cathodic peaks click here shift toward the negative potential, which demonstrates

the quasi-reversible nature of the redox couples [27, 28]. Figure 4 CV and GSK872 datasheet Charging-discharging curves, corresponding specific capacitance, and capacitance retention of Mn 3 O 4 /Ni foam electrode. (a) CV curves of the Mn3O4/Ni foam electrode at different scanning

rates. (b) Charging-discharging curves of the Mn3O4/Ni foam electrode at different current densities. (c) The corresponding specific capacitance as a function of current density. (d) Capacitance retention of the Mn3O4/Ni foam electrode as a function of cycle number. The insert shows the charging-discharging profiles of the first ten cycles recorded with a current density of 1 A · g-1. The charging-discharging curves of the Mn3O4/Ni foam were measured at various current densities (shown in Figure 4b). The specific capacitance was calculated according to the following equation: where C (F · g-1) is the specific capacitance; i (A · g-1) is the discharge current density, Δt (s) is the discharge time, and ΔV (V) is the discharge

potential range. The specific Selleck Torin 1 capacitance values of the Mn3O4/Ni foam composite evaluated from the discharge curves are 293, 263, 234, 214, and 186 F · g-1 at the current density of 0.5, 1, 2, 3, and 5 A · g-1, respectively (Figure 4c). The significant STK38 capacitance decrease with increasing discharge current density is likely to be caused by the increase of potential drop due to electrode resistance and the relatively insufficient Faradic redox reaction of the Mn3O4/Ni foam composite under higher discharge current densities. It is noteworthy that the specific capacitance of the as-prepared Mn3O4/Ni foam composite is higher than of the previously reported Mn3O4 in other forms, i.e., Ma et al. reported a specific capacitance of 130 F · g-1 (in 1 M Na2SO4 electrolyte at a current density of 1 A · g-1) for Mn3O4/graphene nanocomposites prepared by a one-step solvothermal process [29], and Wang et al. reported a specific capacitance of 159 F · g-1 (in 6 M KOH electrolyte at a scan rate of 5 mV · s-1) for Mn3O4/graphene synthesized by mixing graphene suspension in ethylene glycol with MnO2 organosol [30]. The high capacitance of the as-prepared Mn3O4/Ni foam composite can be attributed to the positive synergistic effects between Mn3O4 and Ni foam.