Efficient Oxygen Reduction Reaction (ORR) Catalysts Based on Single Iron Atoms Dispersed on a Hierarchically Structured Porous Carbon Framework

Zhang, Zhengping; Sun, Junting; Wang, Rui; Dai, Liming

doi:10.1002/ange.201804958

Cited by 149 publications

(106 citation statements)

References 66 publications

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“…The large surface area and hierarchical pore of Fe SA -N-C would make the single Fe atoms readily accessible and guarantee high-flux mass transfer, which are essential to boost the catalysis 42 , and oxidized N (402.9 eV), respectively (Supplementary Fig. 11a) [27][28][29][34][35][36][37][38]43 . The Fe 2 p 3/2 binding energy in Fe SA -N-C centers at 710.5 eV (close to Fe 3+ ), suggesting the positively charged Fe atoms ( Supplementary Fig.…”

Section: Resultsmentioning

confidence: 99%

Nanocasting SiO2 into metal–organic frameworks imparts dual protection to high-loading Fe single-atom electrocatalysts

et al. 2020

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Single-atom catalysts (SACs) have sparked broad interest recently while the low metal loading poses a big challenge for further applications. Herein, a dual protection strategy has been developed to give high-content SACs by nanocasting SiO 2 into porphyrinic metal-organic frameworks (MOFs). The pyrolysis of SiO 2 @MOF composite affords singleatom Fe implanted N-doped porous carbon (Fe SA-N-C) with high Fe loading (3.46 wt%). The spatial isolation of Fe atoms centered in porphyrin linkers of MOF sets the first protective barrier to inhibit the Fe agglomeration during pyrolysis. The SiO 2 in MOF provides additional protection by creating thermally stable FeN 4 /SiO 2 interfaces. Thanks to the high-density Fe SA sites, Fe SA-N-C demonstrates excellent oxygen reduction performance in both alkaline and acidic medias. Meanwhile, Fe SA-N-C also exhibits encouraging performance in proton exchange membrane fuel cell, demonstrating great potential for practical application. More far-reaching, this work grants a general synthetic methodology toward high-content SACs (such as Fe SA , Co SA , Ni SA).

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Section: Resultsmentioning

confidence: 99%

Nanocasting SiO2 into metal–organic frameworks imparts dual protection to high-loading Fe single-atom electrocatalysts

et al. 2020

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“…With atomically metal dispersity, such single-site catalysts display several distinct advantages in the maximized atom efficiency, strengthened selectivity towards targeted product, improved intrinsic activity, and facilitative recyclability 5 , 6 . Indeed, single-site catalysts, including Au 7 , 8 , Pt 9 , 10 , Pd 11 , 12 , Ru 13 , 14 , Ir 15 , 16 , Rh 17 , Fe 18 – 20 , Co 21 , 22 , Ni 23 – 25 , Mn 26 , Mo 27 , and W 28 , are reported over past few years and exhibit interesting activity in CO oxidation, solar energy conversion, hydrogen production, hydrogenation, CO 2 reduction, and oxygen reduction reaction. To date, several synthetic protocols have been reported for fabricating single-site catalysts including photochemical reduction 2 , co-precipitation 3 , atomic layer deposition (ALD) 13 , wet impregnation 29 , and so on.…”

Section: Introductionmentioning

confidence: 99%

A cocoon silk chemistry strategy to ultrathin N-doped carbon nanosheet with metal single-site catalysts

et al. 2018

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Development of single-site catalysts supported by ultrathin two-dimensional (2D) porous matrix with ultrahigh surface area is highly desired but also challenging. Here we report a cocoon silk chemistry strategy to synthesize isolated metal single-site catalysts embedded in ultrathin 2D porous N-doped carbon nanosheets (M-ISA/CNS, M = Fe, Co, Ni). X-ray absorption fine structure analysis and spherical aberration correction electron microscopy demonstrate an atomic dispersion of metal atoms on N-doped carbon matrix. In particular, the Co-ISA/CNS exhibit ultrahigh specific surface area (2105 m2 g−1) and high activity for C–H bond activation in the direct catalytic oxidation of benzene to phenol with hydrogen peroxide at room temperature, while the Co species in the form of phthalocyanine and metal nanoparticle show a negligible activity. Density functional theory calculations discover that the generated O = Co = O center intermediates on the single Co sites are responsible for the high activity of benzene oxidation to phenol.

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“…The XPS survey spectrum of PNKA‐800 (Figure a), shows obvious signals belonging to the C, N, O, and P, validating the existence of afore mentioned element in prepared carbon samples. Figure b shows the high‐resolution C1s spectra, a dominant peak at 284.8 eV, combined with two small peaks distributed at 285.9 eV and 287.6 eV could be observed . As presented in the Figure c, the N 1s spectra could be deconvoluted into three peaks located at 398.8, 399.8, and 401.1 eV, corresponding to the pyridine, pyrrole, and graphitic N species, respectively .…”

Section: Resultsmentioning

confidence: 86%

Porous Organic Polymers as Fire‐Resistant Additives and Precursors for Hyperporous Carbon towards Oxygen Reduction Reactions

Xue

Dou

et al. 2020

ChemistryOpen

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Cyclotriphosphazene (CP) based porous organic polymers (POPs) have been designed and prepared. The introduction of CP into the porous skeleton endowed special thermal stability and outstanding flame retardancy to prepared polymers. The nonflammable level of PNK-CMP fabricated via the condensation of 2,2'-(1,4-phenylene)diacetonitrile (DAN) and hexakis(4acetylphenoxy)cyclotriphosphazene (HACTP) through Knoevenagel reaction, in vertical burning tests reached V-2 class (UL-94) and the limiting oxygen index (LOI) reached 20.8 %. When used as additive, PNK-CMP could suppress the dissolving out of PEPA effectively, reducing environment pollution and improv-ing the flame retardant efficiency. The POP and PEPA co-added PU (m POP %: m PEPA % = 5.0 %: 5.0 %) could not be ignited under simulated real-scale fire conditions. The nonflammable level of POP/PEPA/PU in vertical burning tests (UL-94) reached V-0 class with a LOI as high as 23.2 %. The smoke emission could also be suppressed, thus reducing the potential for flame spread and fire hazards. Furthermore, carbonization of PNK-CMP under the activation of KOH yield a hyperporous carbon (PNKA-800) with ultrahigh BET surface area (3001 m 2 g À 1 ) and ultramicropore size showing excellent ORR activity in alkaline conditions.

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Efficient Oxygen Reduction Reaction (ORR) Catalysts Based on Single Iron Atoms Dispersed on a Hierarchically Structured Porous Carbon Framework

Cited by 149 publications

References 66 publications

Nanocasting SiO2 into metal–organic frameworks imparts dual protection to high-loading Fe single-atom electrocatalysts

Nanocasting SiO2 into metal–organic frameworks imparts dual protection to high-loading Fe single-atom electrocatalysts

A cocoon silk chemistry strategy to ultrathin N-doped carbon nanosheet with metal single-site catalysts

Porous Organic Polymers as Fire‐Resistant Additives and Precursors for Hyperporous Carbon towards Oxygen Reduction Reactions

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