Operando reconstruction of solid catalyst
into
a distinct active state frequently occurs during electrocatalytic
processes. The correlation between initial and operando states, if ever existing, is critical for the understanding and
precise design of a catalytic system. Inspired by recently established
intermediate metallic state of Bi-based catalysts during electrocatalytic
carbon dioxide reduction (CO2RR), here we investigate a
series of Bi oxide catalysts (Bi, Bi2O3, BiO2) and demonstrate that the operando surface/subsurface
oxygen loading, positively correlated to the initial oxygen content,
plays a critical role in determining Bi-based CO2RR performance.
Higher initial oxygen loading indicates a better electrocatalytic
efficiency. Further analysis shows that this conclusion generally
applies to all Bi-based electrocatalysts reported up to date. Following
this principle, cost-effective BiO2 nanocrystals demonstrated
the highest formate Faradaic efficiency (FE) and current density compared
to Bi/Bi2O3, further allowing a pair-electrolysis
system with 800 mA/cm2 current density and an overall 175%
FE for formate production.