Abstract
The electrochemical reduction of CO(2) (CO(2) RR) is a promising approach to maintain a carbon cycle balance and produce value-added chemicals. However, CO(2) RR technology is far from mature, since the conventional CO(2) RR electrocatalysts suffer from low activity (leading to currents <10 mA cm(-2) in an H-cell), stability (<120 h), and selectivity. Hence, they cannot meet the requirements for commercial applications (>200 mA cm(-2) , >8000 h, >90 % selectivity). Significant improvements are possible by taking inspiration from nature, considering biological organisms that efficiently catalyze the CO(2) to various products. In this minireview, we present recent examples of enzyme-inspired and enzyme-mimicking CO(2) RR electrocatalysts enabling the production of C(1) products with high faradaic efficiency (FE). At present, these designs do not typically follow a methodical approach, but rather focus on isolated features of biological systems. To achieve disruptive change, we advocate a systematic design methodology that leverages fundamental mechanisms associated with desired properties in nature and adapts them to the context of engineering applications.