Efficient reduction of CO2 to CO by CdAl-LDHs nanostructured electrocatalysts in ionic liquids

Abstract

Layered bimetallic hydroxides are at the forefront of current research in electrocatalytic materials. Although there is considerable research on various bimetallic hydroxides, the study of bimetallic hydroxides for electrocatalytic reduction of carbon dioxide is limited. In this paper, cadmium-aluminum layered bimetallic hydroxide nanoparticles (CdAl-LDHs) were prepared using a simple electrochemical deposition method. The prepared CdAl-LDHs was characterized in detail, and its potential application as an electrocatalyst was discussed. CdAl-LDHs prepared using different methods showed different selectivity in the electrocatalytic reduction of CO2 to CO. The nanomaterial exhibits excellent CO selectivity in a reaction chamber using 2 %-BMIM(PF6)(1-butyl-3-methylimidazolium hexafluorophosphate)/DMF(N-N dimethyl formamide) as the electrolyte. The CdAl-LDHs prepared by electrochemical deposition exhibited a maximum CO partial current density of 22.13 mA cm−2 with a remarkable CO Faraday efficiency (FE) of 99.71 %, which is comparable to or even higher than that of noble metal catalysts. This high selectivity for CO indicates its potential as an alternative to expensive noble metal catalysts. Moreover, the catalyst demonstrated high stability over 30 h of continuous operation with stable FE of around 99 % and a current density of around 10.5 mA cm−2, with minimal degradation during the entire reaction cycle. In addition, the catalyst showed a low HER current density of less than 0.1 mA cm−2 at all tested potentials, indicating that the catalyst maintains a high level of CO2 conversion over the entire range of tested potentials. This suggests its great potential for industrial applications.