Atomically dispersed iron sites within N-enriched C-networks are promising low-cost catalytic materials for electrochemical applications. At odds with their often-outstanding performance in challenging electrocatalytic processes (i.e. oxygen reduction reaction, ORR) their fabrication strategy frequently relies on trial-and-error approaches. Moreover, the complex chemical nature of these hybrids is often dictated by the use of highly aggressive etching/doping thermo-chemical treatments. Therefore, the development of simplified chemical protocols based on cheap and abundant raw materials ensuring highly reproducible synthetic paths with the prevalent generation of discrete single-atom sites in a definite coordination environment, remains challenging issue to be properly addressed. In this contribution, the synthesis of hierarchically porous and N-enriched C-networks, prevalently containing Cl-FeN4 sites is proposed. The outlined procedure takes advantage of citrate ions as carriers for N-sites and sacrificial C-source for the synthesis of N/C matrices. At the same time, the chelating character of the citrate polyions foster the complexation of transition metals for their ultimate atomical dispersion in C/N matrices. The procedure is finally adapted to the use of common inorganic hard templates and porogens for the control of the material morphology. Avoiding any thermo-chemical etching/doping phase, the as-prepared catalytic material has shown remarkably high ORR performance under alkaline environment. With a half-wave potential (E1/2) of 0.88 V, kinetic current density up to 109.6 A g-1 (normalized to the catalyst loading at 0.8 V vs. RHE) and outstanding stability, it largely outperforms commercial Pt/C catalyst and certainly ranks among the most performing ORR Fe-single-atom-catalysts (Fe-SACs) reported so far.
Inducing atomically dispersed Cl-FeN4 sites for ORRs in the SiO2-mediated synthesis of highly mesoporous N-enriched C-networks / Zhang X; Truong-Phuoc L; Liao XM; Papaefthimiou V; Pugliesi M; Tuci G; Giambastiani G; Pronkin S; Pham-Huu C. - In: JOURNAL OF MATERIALS CHEMISTRY. A. - ISSN 2050-7488. - ELETTRONICO. - (2022). [10.1039/d1ta09519f EA NOV 2021]
Inducing atomically dispersed Cl-FeN4 sites for ORRs in the SiO2-mediated synthesis of highly mesoporous N-enriched C-networks
Giambastiani G;
2022
Abstract
Atomically dispersed iron sites within N-enriched C-networks are promising low-cost catalytic materials for electrochemical applications. At odds with their often-outstanding performance in challenging electrocatalytic processes (i.e. oxygen reduction reaction, ORR) their fabrication strategy frequently relies on trial-and-error approaches. Moreover, the complex chemical nature of these hybrids is often dictated by the use of highly aggressive etching/doping thermo-chemical treatments. Therefore, the development of simplified chemical protocols based on cheap and abundant raw materials ensuring highly reproducible synthetic paths with the prevalent generation of discrete single-atom sites in a definite coordination environment, remains challenging issue to be properly addressed. In this contribution, the synthesis of hierarchically porous and N-enriched C-networks, prevalently containing Cl-FeN4 sites is proposed. The outlined procedure takes advantage of citrate ions as carriers for N-sites and sacrificial C-source for the synthesis of N/C matrices. At the same time, the chelating character of the citrate polyions foster the complexation of transition metals for their ultimate atomical dispersion in C/N matrices. The procedure is finally adapted to the use of common inorganic hard templates and porogens for the control of the material morphology. Avoiding any thermo-chemical etching/doping phase, the as-prepared catalytic material has shown remarkably high ORR performance under alkaline environment. With a half-wave potential (E1/2) of 0.88 V, kinetic current density up to 109.6 A g-1 (normalized to the catalyst loading at 0.8 V vs. RHE) and outstanding stability, it largely outperforms commercial Pt/C catalyst and certainly ranks among the most performing ORR Fe-single-atom-catalysts (Fe-SACs) reported so far.File | Dimensione | Formato | |
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J. Mater. Chem. A, 2022, asap. DOI 10.1039_D1TA09519F.pdf
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