39 V (vs Ag/AgCl) for the NiO NPs and NFs, respectively; these v

39 V (vs. Ag/AgCl) for the NiO NPs and NFs, respectively; these values are good compared with many reported materials. Figure 4 Linear scan voltammograms for the methanol oxidation on the NiO NPs and NFs

surfaces. Cyclic voltammograms at a scan rate of 50 mVs−1 and 25°C for NiO NPs and NFs in 1 M KOH and different methanol concentrations. Two important findings can be observed in Figure 4: First, the nanofibrous morphology strongly enhances the electrocatalytic activity as the maximum current density significantly increased from 6 (in case of NPs) to 25 mA/cm2 (in case of NFs). Second, the optimum methanol concentration increased from 0.1 M in case of nanoparticulate morphology to 1 M RAD001 concentration in case of the nanofibers. Actually, concentrated methanol solution is a target fuel in the DMFCs to reduce the volume. However, increasing of methanol concentration can have a negative influence on the current density, so each electrocatalyst corresponds to a certain methanol concentration. The obtained

good performance of the nanofibrous morphology can be assigned to the influence of the one-dimensional feature which facilitates the electron transfer through the electrocatalyst. It is expected that the electron paths through the nanoparticles will be corrugated; however, as the nanofibers have very high axial ratio, almost straight paths are expected. Moreover, within Quisinostat manufacturer the nanoparticles, the electrons pass through several contact points as they have to move through many nanoparticles; this adds more constraints for the electrons transfer which distinctly affects the catalyst performance. Figure 5 shows a conceptual illustration Farnesyltransferase for the electrons paths through the nanofibrous and nanoparticulate electrocatalysts. Figure 5 Schematic diagram showing the electron paths in

case of NiO nanofibers and nanoparticles. Conclusions Electrospinning technique can be utilized to fabricate NiO nanofibers from PVP and nickel acetates sol–gel. The morphology has a distinct influence on the electrocatalytic activity of the nickel oxide nanostructures toward methanol oxidation. Compared to the nanoparticles, the nanofibrous morphology facilitates the electrons’ motion which positively affects the performance. It is expected that the good impact of the nanofibrous morphology is a common feature, so it can be utilized with other electrocatalytic materials. Acknowledgements This research was supported by NPST program by King Saud University project number 11-ENE1721-02. Also, this work was supported by the National Research Foundation of Korea (NRF) grant funded by the Korea government (MEST) (no. 2012R1A2A2A01046086). Selleckchem Barasertib References 1. Barakat NAM, Abadir MF, Nam KT, Hamza AM, Al-Deyab SS, Baek W-I, Kim HY: Synthesis and film formation of iron-cobalt nanofibers encapsulated in graphite shell: magnetic, electric and optical properties study. J Mater Chem 2011,21(29):10957–10964.CrossRef 2.

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