Journal of Power Sources, Vol.304, 255-265, 2016
Activity and stability studies of titanates and titanate-carbon nanotubes supported Ag anode catalysts for direct methanol fuel cell
Titanate-SWCNT; synthesized via exploiting the interaction between TiO2 anatase with oxygen functionalized SWCNT, supported Ag nanoparticles and Ag/titanate are characterized using XRD, TEM-EDX-SAED, N-2 adsorption, Photoluminescence, Raman and FTIR spectroscopy. These samples are tested for methanol electrooxidation via using cyclic voltammetry (CV) and impedance measurements. It is shown that Ag/titanate nanotubes exhibited superior electrocatalytic performance for methanol oxidation (4.2 mA cm(-2)) than titanate-SWCNT, Ag/titanate-SWCNT and titanate. This study reveals the existence of a strong metal support interaction in Ag/titanate as explored via formation of Ti-O-Ag bond at 896 cm(-1) and increasing surface area and pore volume (103 m(2) g(-1), 0.21 cm(3) g(-1)) compared to Ag/titanate-SWCNT (71 m(2) g(-1), 0.175 cm(3) g(-1)) that suffers perturbation and defects following incorporation of SWCNT and Ag. Embedding Ag preferably in SWCNT rather than titanate in Ag/titanate-SWCNT disturbs the electron transfer compared to Ag/titanate. Charge transfer resistance depicted from Nyquist impedance plots is found in the order of titanate > Ag/titanate-SWCNT > titanate-SWCNT > Ag/titanate. Accordingly, Ag/titanate indicates a slower current degradation over time compared to rest of catalysts. Conductivity measurements indicate that it follows the order Ag/titanate > Ag/titanate-SWCNT > titanate > titanate-SWCNT declaring that SWCNT affects seriously the conductivity of Ag(titanate) due to perturbations caused in titanate and sinking of electrons committed by Ag through SWCNT. (C) 2015 Elsevier B.V. All rights reserved.
Keywords:Ag/titanate-SWCNT;Direct methanol fuel cells;Electrocatalysis;Electrochemical impedance;Electrical conductivity