Electrochemical study of carbon dioxide reduction at copper - palladium nanoparticles: influence of the bimetallic composition in the CO poisoning tolerance.

Abstract A study of the CO2 electrochemical reduction reaction (CO2RR) at Pd100-xCux solid solution type nanoalloys is presented. Cyclic voltammetry and chronoamperometry are used in combination with a cavity microelectrode (CME) for the first time. Low-distorted voltammetric signals obtained with the CME evidence that for alloys with low or moderate Cu content (up to 50 at.%) the typical CO2RR inhibition peak, related to CO blocking Pd active sites, becomes a current plateau. Interestingly, the plateau height matches the theoretical value corresponding to the steady state current of a microdisc. This fact indicates a better tolerance of Pd100-xCux towards CO poisoning and also the attainment of a pseudo-steady state where mass transport should be controlled by diffusion. The synergy between Cu and Pd is thus established for the first time at the level of the voltammograms. The chronoamperometric responses exhibit three well defined regions corresponding to 1) double layer charging and diffusion/reaction establishment, 2) beginning of CO poisoning by formation of a CO adlayer and (3) final collapse of the catalytic activity at a critical time, tc, which depends directly on the bimetallic composition. A plot of tc vs. Pd content exhibits a clear volcano shape, from which ∼ Pd72Cu28 is identified as a close to optimal composition in terms of CO tolerance and Pd35Cu65 as the composition from which the advantage of alloying Pd with Cu is lost. An in-depth analysis of the I/V response and its evolution with composition and time is performed in the CO2RR and CO stripping regions. As a result, the possibility of developing a method to further increase the catalyst lifetime based on periodical releasing of “CO-like” intermediates by CO stripping is proposed.