Rather than just focusing on the catalyst itself in the electrocatalytic CO2 reduction reaction
(eCO2RR), as previously reviewed elsewhere, we herein extend the discussion to the …

Catalytic conversion of CO2 into chemicals and fuels is a viable method to reduce carbon
emissions and achieve carbon neutrality. Through thermal catalysis, electrocatalysis, and …

Solid oxide cells (SOCs) are renowned for their high efficiency in the direct conversion of
various fuels into electricity, as well as their capacity to produce green hydrogen or added …

Excessive exploitation and depletion of fossil fuels have led to the escalation of CO 2
emissions, which are responsible for global climate deterioration. Cu-based solid catalysts …

Zr was doped on Co/CeO 2 cubic catalysts to enhance oxygen storage capacity (OSC) in the
water–gas shift (WGS) reaction using waste-derived synthesis gas. Zr concentrations (0 …

Solid oxide electrolyte membrane is the core component of solid oxide cells and determines
the efficiency of energy conversion. Identifying the failure mechanism of electrolyte …

The surface reaction kinetics of perovskite oxides is usually regulated by the formation of
carriers in the crystal lattice by element doping, but there are few studies on improving the …

Reversible solid oxide cell is a promising energy storage and conversion device for CO2‐
CO mutual conversion, with simplified cell configuration and performance stability. One key …

CeO 2 is often used as the buffer layer for CO 2 electroreduction in solid oxide electrolysis
cells (SOECs) because of their limited electrocatalytic activity and low reactivity with …

Electrodes with a maximal active site density are critical for high‐performance high‐
temperature electrochemical cells (HTECs). One widely employed approach involves the …