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Atomically dispersed metal catalysts have demonstrated superb electrocatalytic activity because of optimal atom efficiency. However, a rational design of low-cost, high-performance single atom catalysts remains a great challenge due to the elusive chemical reactions of the formation of metal active sites. In this work, biomass hydrogel is prepared as a template for mass production of three-dimensional carbon aerogel-supported single metal atom catalysts. By tailoring the structure of the hydrogel templates, the obtained carbon aerogels exhibit an increase of microporous defects which capture and stabilize isolated metal atoms and minimize aggregation during pyrolysis. Extended X-ray absorption fine structure, Mössbauer spectroscopy, and nitrogen adsorption–desorption isotherm measurements indicate that single metal centers of FeN 4 are formed and embedded within the hierarchical porous carbon frameworks. The obtained composites exhibit outstanding catalytic activity towards oxygen reduction in alkaline media, with a high onset potential of +1.05 V and half-wave potential of +0.88 V, as well as excellent durability. Remarkably, when the carbon aerogels are used as the cathode catalyst in an aluminum–air battery, the battery achieves an ultrahigh open-circuit voltage of 1.81 V, large power density of 181.1 mW cm −2 and stable discharge voltage of 1.70 V at 20 mA cm −2 , markedly better than those with commercial Pt/C as the cathode catalyst. 

Abstract Sn‐based materials are identified as promising catalysts for the CO₂electroreduction (CO2RR) to formate (HCOO⁻). However, their insufficient selectivity and activity remain grand challenges. A new type of SnO₂nanosheet with simultaneous N dopants and oxygen vacancies (V_O‐rich N‐SnO₂NS) for promoting CO₂conversion to HCOO⁻is reported. Due to the likely synergistic effect of N dopant andV_O, theV_O‐rich N‐SnO₂NS exhibits high catalytic selectivity featured by an HCOO⁻Faradaic efficiency (FE) of 83% at−0.9 V and an FE of>90% for all C1 products (HCOO⁻and CO) at a wide potential range from −0.9 to−1.2 V. Low coordination Sn–N moieties are the active sites with optimal electronic and geometric structures regulated byV_Oand N dopants. Theoretical calculations elucidate that the reaction free energy of HCOO* protonation is decreased on theV_O‐rich N‐SnO₂NS, thus enhancing HCOO⁻selectivity. The weakened H* adsorption energy also inhibits the hydrogen evolution reaction, a dominant side reaction during the CO2RR. Furthermore, using the catalyst as the cathode, a spontaneous Galvanic Zn‐CO₂cell and a solar‐powered electrolysis process successfully demonstrated the efficient HCOO⁻generation through CO₂conversion and storage.