cm -2 Nanostructure electrode C sd (mF.cm -2) ESR (Ω.cm 2) ZnO nanorod core-PPy sheath 131.22 40.5 Narrow PPy nanotube (2-h etch) 132.28 25.08 Open PPy nanotube (4-h etch) 141.09 32.09 Figure 16 The specific capacitances of the ZnO nanostructured electrodes plotted as a function of charge-discharge current density. Cycling test The cycling stability of the open PPy nanotube electrode was investigated at a constant selleck compound charge-discharge current density of 1 mA.cm-2 for a continuous 5,000 cycles. Figure 17 shows the effect on the discharge capacitance density as a function of the number of charge-discharge cycle. The overall change in the discharge capacitance is only <12% indicative of
highly stable redox performance and electrochemical stability of the PPy nanotube electrode. This stability arises from unimpeded access of the electrolyte ions through diffusive transport across to a large
fraction of the PPy polymer surface due to the 3-D nanotube structure in the redox process. Furthermore, the PPy nanotube electrodes do not show physical or chemical Pifithrin-�� mouse degradation during cycling. This is borne out from the ESR data, which remains on the average nearly constant during cycling tests for 5,000 cycles. Figure 17 Long-term charge-discharge cycle tests for PPy nanotube 4-h etched electrode showing discharge capacitance density and ESR variation. Conclusions Electrodes in the three-dimensional nanoscale architecture studied in this work in the form of vertically aligned 3-mercaptopyruvate sulfurtransferase ZnO nanorod PPy sheath and PPy nanotube show considerable potential for high energy-density storage in a supercapacitor device. These nanostructures are formed by depositing a sheath of PPy over vertical ZnO nanorod arrays by controlled pulsed current electropolymerization and by selective etching of the ZnO nanorod core. Based on the cyclic voltammetry data, electrode with open interconnected PPy nanotube array structure shows high areal-specific capacitance
of approximately 240 mF.cm-2 attributed to realization of enhanced access to electrolyte ions. The observed scan rate dependence of the current has been https://www.selleckchem.com/products/AZD7762.html interpreted as delayed response time of faradic reaction nonsynchronous with faster scan rate, which could possibly have boosted capacitance density further. Slow redox processes are shown to be due to limitation of electron transfer across the length of vertical PPy nanotube arrays rather than the diffusive transport of electrolyte ions. Managing this limitation could possibly enhance the specific capacitance and thus energy storage ability further. Authors’ information NKS is presently a PhD student at the Electrical and Computer Engineering Department at the State University of New York, Binghamton. ACR is Associate Professor at the Electrical and Computer Engineering Department and Associate Director of the Center for Autonomous Solar Power (CASP) at the State University of New York, Binghamton.