Journal
CARBON
Volume 213, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.carbon.2023.118192
Keywords
ORR; Single-atomic catalysts; Electrocatalysis; Density-functional theory (DFT); Fuel cells
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Hollow carbon spheres (CSs) were synthesized with stable single-atom Fe-N species as alternatives to noble metals-based electrocatalysts for oxygen reduction reaction (ORR). The CSs were finely tuned through a synthesis methodology requiring only earth-abundant metal precursors. Single-atom Fe-N active sites were introduced on the CSs, resulting in a significant enhancement in ORR activity. Advanced characterization and molecular simulation studies revealed the crucial role of nitrogen in anchoring individual iron atoms and modulating the charge density nearby the active sites.
Seeking alternatives to noble metals-based electrocatalysts for oxygen reduction reaction (ORR), hollow carbon spheres (CSs) were finely tuned with stable single-atom Fe-N species through a synthesis methodology requiring only earth-abundant metal precursors. CSs with different sizes were synthesized by sol-gel polycondensation of resorcinol with formaldehyde over silica nanoparticles, followed by thermal annealing and silica etching. A catalyst screening revealed the positive impact of both the hollow core and structural defects of the CSs for ORR. Single-atom Fe-N active sites were introduced on the best performing CSs through simultaneous incorporation of iron and nitrogen precursors, and glucose. A significant enhancement in ORR activity was observed despite the small iron load introduced (0.12 wt%). ORR performance indicators, advanced characterization, and molecular simulation studies revealed nitrogen's crucial role in anchoring individual iron atoms and modulating the charge density nearby the active sites (increase of 80 mV in the half-wave potential). Adding glucose as a chelating agent enhances the metal-heteroatom coordination and subsequent dispersion of iron, accounting for an increase of 20 mV in the half-wave potential, an average of electrons transferred as high as 3.9 (at 0.4 V vs. RHE), and higher stability (99%) than that of a platinum-based (20 wt%) electrocatalyst (92%).
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