Nickel Species-Modified Mesoporous SnO2 as a Non-Platinum Electrocatalyst for Bioethanol Anodic Oxidation

Abstract

The effectiveness of mesoporous SnO2 nickel-decoration as a method for obtaining active electrode materials for bioethanol electrochemical oxidation and the way in which the embedment of a small amount of Black Pearls (BP) affects the electrocatalytic performances of Ni/SnO2 systems were investigated. XPS analysis reveals the presence of NiO, Ni(OH)2 and Ni2O3 chemical species which favors the oxidation of bioethanol and improves the COx tolerance. Nickel deposition in a reducing environment does not affect the Sn chemistry and the mesoporosity but significantly increases SBET. A slight amount of BP enhances the SBET value and a induces a small contribution of larger pores appears. Tafel slopes of 80 mV decade−1 were estimated for bioethanol oxidation at Ni/SnO2, which favorably compare to those reported in the literature. It was also found that BP incorporation leads to a decrease of the Tafel slope to 70 mV decade−1, without deleteriously affecting the stability of the electrocatalyst during long-term polarization. EIS results suggested that this improvement might be the combined effect of a lower electrical resistance, a higher specific surface area and a certain contribution from larger pores, which could lead to a better access of the bioethanol species to the electrocatalyst surface.