Sensing and conversion of carbon dioxide to methanol using Ag-decorated zinc oxide nanocatalyst

The modelled and simulated high-performance Ag decorated ZnO nano catalyst depicted outstanding properties for the catalytic hydrogenation of CO ₂ to CH ₃OH and H ₂O molecules with an enhanced sensing response and recovery time, that provide insight into reaction mechanism.

The catalytic hydrogenation of CO ₂ to methanol, which is one of the most important byproducts, has been studied using density functional theory simulations. The chemisorption of silver (Ag) atoms on the ZnO nanocage surface significantly narrowed the bandgap from 4.05 to 1.27 eV and altered the overall optoelectronic and catalytic properties of the nanocage. We introduced a successful two step activation and conversion of carbon dioxide into methanol and water. The high performance of the Ag-decorated ZnO catalyst activated the CO ₂ gas owing to its chemisorbed nature. At this stage, three H ₂ molecules were incorporated to surround the chemisorbed CO ₂ gas, which converted it to methanol (CH ₃OH) and water molecules with an enhanced sensitivity of 70%. This demonstrates maximum sensing response up to 54% at room temperature (300 K), which further lowered the bandgap from 1.23 to 0.70 eV. The calculated recovery time of the Ag-decorated ZnO sensor was 5.06 × 10 ⁻⁰⁹ s, indicating its outstanding optical characteristics, strong chemical stability, and high electron mobility. The adsorption energies of the Ag-decorated and activated CO ₂-adsorbed ZnO complexes were found to be −1.76, and −0.28 respectively, indicating a thermodynamically stable configuration. This study focuses on CO ₂ activation, advances the catalytic hydrogenation of CO ₂ to methanol to develop high-performance catalysts with enhanced sensing responses and recovery times, and provides insight into the reaction mechanisms.