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Electrocatalysis of Alcohol Oxidation and Oxygen Reduction at High pH Environments

Electrocatalysis of Alcohol Oxidation and Oxygen Reduction at High pH Environments. Qingang He, Nagappan Ramaswamy, and Sanjeev Mukerjee. Breakthrough Materials for Alcohol Oxidation. Remarkable improvements in ethanol oxidation performance

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Electrocatalysis of Alcohol Oxidation and Oxygen Reduction at High pH Environments

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  1. Electrocatalysis of Alcohol Oxidation and Oxygen Reduction at High pH Environments Qingang He, Nagappan Ramaswamy, and Sanjeev Mukerjee • Breakthrough Materials for Alcohol Oxidation • Remarkable improvements in ethanol oxidation performance • has been observed on platinum with millimolar concentrations • of the transition metal complex. • Metal organic complex dissolved in ethanol fuel as an additive • cleaves the C=C double bond via a coupled chemical and • electrochemical reaction mechanism on the Pt surface • Cleavage of C=C double bond and evolution of CO2 has been • confirmed using both surface sensitive XAS analysis (Delta-Mu) • and Differential Electrochemical Mass Spectrometry (DEMS) • Oxygen reduction on non-noble metal surface involving pyrolyzed • metal macrocyle has been observed to exhibit ORR activity similar • to that of platinum • Combination of square wave voltammetry and insitu XANES has been • used to elucidate that the anodic redox potential shift of M(III)/M(II) with • increasing pyrolysis temperature as the key to improved ORR activity • Non-PGM Pyrolyzed Macrocyle • for Oxygen Reduction ORR Activity equal to Platinum Northeastern University Center for Renewable Energy Technology, Boston

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