Atomically Dispersed Iron–Nitrogen Active Sites within Porphyrinic

Mar 15, 2018 - Recently, porous covalent triazine frameworks (CTFs) obtained from the .... As shown in Figure 4a, as in alkaline media, the FeSAs/PTF-...
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Atomically Dispersed Iron-Nitrogen Active Sites within Porphyrinic Triazine-based Frameworks for Oxygen Reduction Reaction in Both Alkaline and Acidic Media Jun-Dong Yi, Rui Xu, Qiao Wu, Teng Zhang, Ke-Tao Zang, Jun Luo, Yu-Lin Liang, Yuan-Biao Huang, and Rong Cao ACS Energy Lett., Just Accepted Manuscript • DOI: 10.1021/acsenergylett.8b00245 • Publication Date (Web): 15 Mar 2018 Downloaded from http://pubs.acs.org on March 15, 2018

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Atomically Dispersed Iron-Nitrogen Active Sites

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within Porphyrinic Triazine-based Frameworks

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for Oxygen Reduction Reaction in Both Alkaline

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and Acidic Media

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Jun-Dong Yi,†,‡,# Rui Xu,†,‡,# Qiao Wu,†,# Teng Zhang,† Ke-Tao Zang,§ Jun Luo,§ Yu-Lin Liang,Ⅱ

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Yuan-Biao Huang,*,† and Rong Cao*,†,‡

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Dedicated to Professor Xin-Tao Wu on the occasion of his 80th birthday

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State Key Laboratory of Structural Chemistry, Fujian Institute of Research on the Structure of

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Matter, Chinese Academy of Sciences, Fuzhou 350002, China

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University of the Chinese Academy of Sciences, Beijing 100049, China

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§

Center for Electron Microscopy, Institute for New Energy Materials and Low-Carbon

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Technologies, School of Materials, Tianjin University of Technology, Tianjin 300384, China

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Academy of Sciences, Shanghai 201204, China

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#

Shanghai Synchrotron Radiation Facility, Shanghai Institute of Applied Physics, Chinese

J.Y., R.X. and Q.W. contributed equally.

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ABSTRACT: The rational design of highly efficient, low-cost and durable electrocatalysts to

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replace platinum-based electrodes for oxygen reduction reaction (ORR) is highly desirable.

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Although atomically dispersed supported metal catalysts often exhibit excellent catalytic

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performance with maximized atom efficiency, the fabrication of single atom catalyst remains

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great challenge due to their easy aggregation. Herein, a simple ionothermal method was

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developed to fabricate atomically dispersed Fe-Nx species on porous porphyrinic triazine-based

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frameworks (FeSAs/PTF) with high Fe loading up to 8.3 wt%, resulting in highly reactive and

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stable single-atom ORR catalysts for the first time. Owning to the high density of single-atom

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Fe-N4 active sites, highly hierarchical porosity and good conductivity, the as-prepared catalyst

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FeSAs/PTF-600 exhibited highly efficient activity, methanol-tolerance and superstability for

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oxygen reduction reaction (ORR) under both of alkaline and acidic conditions. This work will

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bring new inspiration to design highly efficient noble-metal-free catalysts at the atomic scale for

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energy conversion.

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The rapid consumption of fossil fuels and the accompanying environment pollution has forced us

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to develop sustainable energy conversion technologies.1 Fuel cells and metal–air batteries, in

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which the cathode are driven by oxygen reduction reaction (ORR), are considered as promising

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clean energy candidates for electrical vehicles.2 However, the high overpotential for ORR with

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sluggish kinetic processes is one of the main challenges that impede the large-scale

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commercialization of these clean energy devices. Although the precious Pt-based electrocatalysts

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have shown high activity for ORR, the drawbacks including high cost, scarcity and poor

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durability, as well as MeOH crossover have limited its large-scale practical applications.3-6

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Therefore, it is urgent to develop highly efficient non-noble metal electrocatalysts with excellent

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durability and resistance to MeOH to replace Pt-based electrodes.7-9 Over the past decade, earth-

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abundant-metal-based electrocatalysts toward ORR have been extensively inverstigated.10-13 In

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particular, Fe-based catalysts supported in carbons have been demonstrated to be one of the most

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promising candidates to replace Pt-based catalysts. It has been proved that Fe-Nx species are the

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active sites for ORR.14-19 Nevertheless, most of the Fe-based materials often contains various Fe-

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based species (such as FeNx, Fe, Fe3C), thereby hindering the discrimination of the active sites.

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Designing and fabricating atomically dispersed active Fe-Nx species is a promising method to

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identify the active sites at the molecular level because single-atom catalysts (SACs) could bridge

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the gap between heterogeneous and homogeneous catalysis. Furthermore, the low-coordinated

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SACs possess exposed active sites, thus maximizing the metal atom efficiency and usually

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achieving high catalytic performance.20-24 Despite much effort has been devoted to fabricate

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SACs, it is still a great challenge to prepare atomically dispersed metal species because of their

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easy migration and agglomeration.25-28 To this end, it is highly desirable to develop suitable

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supports to provide strong interaction with Fe single atoms for achieving highly efficient in

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ORR.29-34 However, so far, most SACs are stabilized by the defects or voids of metal oxides,35-37

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which cannot be employed as electrocatlysts because of their poor electrical conductivity.

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Therefore, the judicious choice of suitable support containing anchoring points or vacancies with

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good electrical conductivity is very important for preparation single-atom catalysts (SACs) with

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high ORR efficiency.

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Recently, porous covalent triazine frameworks (CTFs) that obtained from the trimerization of

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aromatic nitriles have emerged as promising multifunctional materials for separation and

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catalysis owning to their large surface areas and superstability.38-41 Therefore, the rich N-sites,

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defects in porous CTFs could serve as anchoring points to stabilize SAs.42,43 Moreover, the CTFs

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synthesized by ionothermal method possess good electrical conductivity because partial

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graphitization will be inevitably occurred at high temperature, which is beneficial for

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electrocatalysis. However, only a few examples of single atoms anchored on CTFs have been

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reported to date,42,43 and their applications in electrocatalysis have not been extensively explored.

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More importantly, porphyrin architectures containing four pyrrolic nitrogen sites could act as

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anchoring points to stabilize single-atom metals (e.g. Fe, Co) for effective promotion of ORR.44-

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46

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endow atomically dispersed Fe-Nx species that can behave as open active sites for

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electrocatalysis.

Thus, the implantation of functional metalloporphyrin-like units into porous CTFs could

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Herein, we fabricate highly stable atomically dispersed Fe-N4 species on porous porphyrinic

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triazine-based frameworks (FeSAs/PTFs) with excellent ORR activity via a direct de nova

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synthesis strategy under ionothermal conditions. Thanks to the highly porous structure, the

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highly density of the atomically dispersed Fe-N4 active sites could be exposed to the highly

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diffused reactive species. Consequently, the optimal catalyst FeSAs/PTF-600 obtained at 600 oC

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with good enhanced electrical conductivity exhibited excellent activity, stability and methanol-

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tolerance for ORR in both of alkaline and acidic electrolytes, which surpasses or is comparable

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to the commercial Pt/C catalyst. Our work will pave a new avenue for rational design of highly

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effective catalysts at atomic level.

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As shown in Scheme 1, FeSAs/PTFs were easily obtained by the trimerization reaction of

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Scheme 1. Schematic illustration of the formation of FeSAs/PTF.

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5,10,15,20-tetrakis(4-cyanophenyl)porphyrinato]-Fe(III) chloride (Fe-TPPCN) catalyzed by

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molten zinc chloride in an evacuated pyrex ampoule at 400-600 oC for 40 h, followed by removal

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of ZnCl2 using diluted hydrochloric acid. The resultant samples are labeled as FeSAs/PTF-x (x =

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temperature) based on the ionothermal temperature. Herein, the molten zinc chloride not only

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acted as Lewis acid to promote the trimerization reaction, but also served as porogenic agent to

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produce mesopores. As shown in Figure S1 of the FT-IR spectra, the disappearance of the

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characteristic band of carbonitrile at 2227 cm-1 suggested an almost complete conversion, while

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the presence of a strong absorption band at 1564 cm-1 assigned to triazine rings indicated the

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successful trimerization reaction.38-43 After polymerization, the formed FeSAs/PTFs samples

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showed significantly enhanced thermal stability (Figure S2). Interestingly, the samples

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FeSAs/PTF-400, FeSAs/PTF-500, and FeSAs/PTF-600 have very high Fe contents of 8.3, 7.7,

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and 2.6 wt%, respectively, based on the ICP-AES (inductively coupled plasma atomic emission

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spectroscopy) results (Table S1). It is worth mentioning that the partial pyrolysis of Fe porphyrin

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moieties at higher temperature resulted in a sharp decrease of the Fe loading in FeSAs/PTF-600

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(Figure S2). Nevertheless, the Fe loading of 2.6 wt% is higher than those most of reported metal

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single-atom catalysts.25-28 Such abundant Fe active sites could promote the activity of ORR.

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As illustrated in the powder X-ray diffraction (PXRD) patterns (Figure 1a), FeSAs/PTF-400

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Figure 1. a) PXRD patterns and b) Raman spectra of FeSAs/PTF-400, 500, 600. c) Nyquist plots

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of different samples over the frequency range from 100 kHz to 10 mHz. d) N2 adsorption-

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desorption isotherms of FeSAs/PTFs.

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and FeSAs/PTF-500 show similar patterns and only possess a broad peak centered at 25.6o,

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which may be assigned to the amorphous (002) reflection of graphitic carbon or (001) of

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aromatic sheets.38 While in FeSAs/PTF-600, an additional weak peak at 43.0o was observed and

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corresponded to the (100)/(101) reflections of graphitic carbon, suggesting that a higher graphitic

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degree were produced at 600 oC. Interestingly, no diffraction peak assigned to Fe-based particles

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or carbides was appeared, indicating that atomically dispersed Fe species might be confined in

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the PTFs. The Raman spectra (Figure 1b) also confirmed that any Fe-based particles were absent

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in the FeSAs/PTFs samples. Interestingly, the high ratios of the G-band and D-band intensity

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(IG/ID) and a broad 2D peak at ca. 2800 cm-1 were observed, which indicated some layered

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graphene-like architectures were presented in all the three FeSAs/PTFs. Meanwhile, the X-ray

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photoelectron spectroscopy (XPS) measurements manifested that the ratio of graphitic N

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increases along with the increment of synthesis temperature (Figure S3, Table S2). These results

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implied that partial graphitization for the FeSAs/PTFs, particularly FeSAs/PTF-600, was

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occurred. The graphitic degree of FeSAs/PTF-600 can be estimated as 64.3% and the details are

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presented in the Supporting Information. This was further confirmed by the electrochemical

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impedance spectroscopy (EIS) measurement. The Nyquist plots (Figure 1c and Table S3)

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demonstrate that FeSAs/PTF-600 shows the minimum semi-circle, implying that this material

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has the best conductivity among the three FeSAs/PTFs materials. This partial graphitization

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phenomenon could facilitate accelerating the electron transfer, thereby improving the activity of

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electrocatalysis.

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Although their amorphous feature, all the FeSAs/PTFs materials show large N2 adsorption

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uptakes and have high BET (Brunauer–Emmett–Teller) surface areas of up to 1067 cm3g-1

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(Figure 1d and Table S4). Moreover, obvious hysteresis loops were observed at the P/Po range of

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0.45–1.0, suggesting meso-, and/or macropores were produced in all the FeSAs/PTFs, which was

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attributed to the porogenic agent ZnCl2. The pore size distributions by non-local density

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functional theory (NL-DFT) method (Figure S4) for FeSAs/PTFs demonstrated that their pores

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are in the range of 1-6 nm. Such highly porous structure could make more active sites expose to

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the accessible reactive species, thus facilitating mass transportation and maximizing atom

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utilization efficiency.

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Figure 2. a) TEM image of FeSAs/PTF-600. b) Corresponding EDS mapping reveals the

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homogeneous distribution of Fe, C, and N elements. c, d) HAADF-STEM images and enlarged

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images of FeSAs/PTF-600. Part of single Fe atoms highlighted by red circles.

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Transmission electron microscopy (TEM), high-angle annular dark-field scanning

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transmission electron microscope (HAADF-STEM) and aberration-corrected HAADF-STEM

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with subangstrom resolution measurements were further conducted to investigate the atomic

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level of Fe sites in FeSAs/PTFs. As shown in Figure 2a and Figure S5-7, no visible Fe particles

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were observed in the TEM and HAADF-STEM images for all the three FeSAs/PTFs samples,

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which is consistent with the PXRD (Figure 1a) and Raman measurement results (Figure 1b).

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Interestingly, the element mapping images (Figure 2b) reveal that Fe element was

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homogeneously distributed over the entire architecture, suggesting that Fe species in an

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atomically dispersed form. The aberration-corrected HAADF-STEM measurements further

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proved the formation of the Fe SAs. A number of bright dots with atomic dispersion in Figure

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2c-d for FeSAs/PTF-600 could be ascribed to the heavier Fe SAs.29-34

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Figure 3. Electrochemical evaluation of catalysts in alkaline media. a) Linear sweep

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voltammograms (LSVs) of FeSAs/PTF-400, 500, 600 and Pt/C at 1600 rpm in O2-saturated 0.1

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M KOH (scan rate: 10 mV s-1). b) LSVs of FeSAs/PTF-600 at different rotation speeds (inset: K-

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L plots and electron transfer numbers). c) Corresponding Tafel plots obtained from the RDE

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polarization curves. d) Electron transfer number of different samples obtained from the RRDE

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curves. e) Methanol-crossover effects test of FeSAs/PTF-600 and Pt/C. f) Current-time

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chronoamperometry for FeSAs/PTF-600 and Pt/C in an O2-saturated 0.1 M KOH solution. g)

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LSVs of FeSAs/PTF-600, FeNPs/PTF-600 and PTF-600 without metal loaded. h) LSVs of

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FeSAs/PTF-600 before and after the addition of 0.1M NaSCN in 0.1 M KOH. i) LSVs of

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poisoned FeSAs/PTF-600 in 0.1 M KOH.

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The atomically dispersed Fe sites with high density in porous FeSAs/PTFs could allow them as

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promising earth-abundant electrocatalysts for oxygen reduction reaction (ORR). The

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FeSAs/PTFs catalysts were investigated on a rotating disk electrode (RDE) in O2-saturated 0.1 M

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KOH solution. As shown in Figure 3a, among the three single-atom catalysts, FeSAs/PTF-600

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exhibits the highest activity with the most positive onset potential Eonset (1.01 V vs. RHE) and

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half-wave potential E1/2 (0.87 V vs. RHE), which are much more positive than those of the

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commercial 20 wt% Pt/C (Eonset = 0.95 V and E1/2 = 0.81 V, respectively). Notably, it is one of

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the best values among all the reported non-precious metal catalysts (Table S5). Meanwhile,

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FeSAs/PTF-600 also possesses the largest diffusion limiting current density of 5.51 mA cm-2

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(0.2 V vs. RHE), which surpassed that of the Pt/C catalyst (5.14 mA cm-2). The Koutecky-Levich

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(K-L) plots for FeSAs/PTF-600 calculated from the LSV polarization curves at different rotation

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speeds (Figure 3b) displayed nearly parallel fitting lines, indicating first-order reaction kinetics

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associated with O2 concentration and a potential-independent electron transfer rate. Furthermore,

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the smaller Tafel slope of 62 mV dec-1 for FeSAs/PTF-600 (Figure 3c), compared with that of

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Pt/C (76 mV dec-1), further verified its superior activity. Very low yields of the two-electron

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product H2O2 were produced based on the RRDE measurements, indicating an efficient four-

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electron transfer process (Figure S8). The electron transfer numbers (n) for FeSAs/PTF-600

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calculated according to rotating ring disk electrode (RRDE) tests are 3.88 (E = 0.2 V vs. RHE)

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(Figure 3d), which are very close to that of Pt/C (n = 3.95) with a four-electron ORR pathway.

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To examine the methanol crossover effects and durability, chronoamperometric tests were

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carried out. As shown in Figure 3e, there was no obvious change in the current density on

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FeSAs/PTF-600 electrode after injecting 1.0 M methanol into the electrolyte, indicating that

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FeSAs/PTF-600 was nearly free from the methanol crossover effect. In contrast, a dramatic

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decrease in the current density for Pt/C was observed under the same conditions. Moreover,

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FeSAs/PTF-600 exhibited a superior stability than the commercial Pt/C catalyst (Figure 3f).

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After 8 h continuous potential cycling test, only a slight peak current decrease was occurred for

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FeSAs/PTF-600, while 17% current decrease was observed for Pt/C. Such long-term durability

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can be ascribed to that the single-atom Fe species were stabilized by the unique porphyrin-like

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structure in the CTF.

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To confirm the active site, a series of control experiments were conducted. For comparison, the

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Fe-free catalysts were also prepared by direct synthesis from 5,10,15,20-tetraki(4-

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cyanophenyl)porphyrin (TPPCN) at 600 oC (denoted as PTF-600) or removal of Fe species from

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FeSAs/PTF-600 in the presence of trifluoromethanesulfonic acid, which was labeled as (Fe)PTF-

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600. As shown in Figure 3g, compared with FeSAs/PTF-600, both of PTF-600 and (Fe)PTF-600

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showed very poor activity for the ORR, which indicated that the activity of FeSAs/PTF-600

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catalyst was largely attributed to Fe sites. In order to further prove the result, the atomic

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dispersed Fe species in FeSAs/PTF-600 were poisoned by SCN- ion and then compared their

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ORR performance.29 As shown in Figure 3h, the catalytic activity of FeSAs/PTF-600 decreased

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distinctly in the presence of SCN- ion, as evidenced by more negative Eonset (0.95 V) and E1/2

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(0.85 V). The diffusion limiting current density also decreased obviously from 5.51 mA cm-2 to

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4.42 mA cm-2 (0.2 V vs. RHE). Interestingly, after rinsing several times with water until pH = 7

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and re-measured in 0.1 M O2-saturated KOH electrolyte, the activity of the recovered poisoned

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FeSAs/PTF-600 electrode could reach the level of the fresh catalyst. As shown in Figure 3i, the

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ORR polarization curve positively shifts after first cycle test in the fresh electrolyte. After 15

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cycles, the catalytic activity of the poisoned electrode finally recovered to the original level due

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to the sufficient dissociation of the SCN-. The poisoning and recovery experiments clearly

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elucidated that isolated Fe sites were the origin of high ORR activity of FeSAs/PTF-600.

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Furthermore, the ORR performance of FeSAs/PTFs in O2-saturated 0.1 M HClO4 was also investigated. As shown in Figure 4a, like in alkaline media, the FeSAs/PTF-600 electrode

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Figure 4. Electrochemical evaluation of catalysts in acidic media. a) LSVs of FeSAs/PTF-400,

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500, 600 and Pt/C at 1600 rpm in O2-saturated 0.1 M HClO4 (scan rate: 10 mV s-1). b)

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Corresponding Tafel plots obtained from the RDE polarization curves. c) Electron transfer

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number of different samples obtained by RRDE. d) Current-time chronoamperometry for

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FeSAs/PTF-600 and Pt/C in an O2-saturated 0.1 M HClO4 solution.

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exhibited the highest activity among the three materials with the most positive onset potential of

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0.89 V, which is close to that of the commercial Pt/C (ca. 0.96 V). Moreover, FeSAs/PTF-600

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showed a larger diffusion limiting current density of 5.42 mA cm-2 (0.2 V vs. RHE) and a

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smaller Tafel slope of 81 mV dec-1 (Figure 4b), compared with that of the Pt/C catalyst (4.92 mA

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cm-2 and 91 mV dec-1, respectively ). A negligible H2O2 yield (less than 0.1%) for FeSAs/PTF-

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600 electrode (Figure S9) was observed and the electron transfer number calculated by the

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RRDE curves was 3.99 at the range of 0.2 V to 0.7 V (Figure 4c), suggesting an efficient 4e

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ORR pathway in the acid media. In addition, the FeSAs/PTF-600 catalyst in the acid media also

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showed a much better stability than the Pt/C electrode (Figure 4d) and free from the methanol

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crossover effects (Figure S10).

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Figure 5. a) The normalized Fe K-edge XANES spectra of the FeSAs/PTFs, Fe-TPPCN and Fe

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foil. b) XPS spectra of the Fe 2p region of FeSAs/PTF-400, 500, 600. c) Fourier transform

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EXAFS spectra of different samples. The corresponding EXAFS fitting curves of d) Fe-TPPCN,

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e) FeSAs/PTF-400 and f) FeSAs/PTF-600.

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The previous reported DFT calculation suggested that the atomically dispersed Fe-N4 species

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are active sites for ORR.29-31 To further prove the atomic dispersion of Fe species and figure out

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the highly efficient activity of FeSAs/PTF-600, X-ray absorption near-edge structure (XANES)

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and X-ray absorption fine structure (EXAFS) were recorded for FeSAs/PTFs synthesized at

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various temperatures. As shown the XANES in Figure 5a, a weak pre-edge peak at about 7113

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eV was appeared in all the FeSAs/PTFs and the precursor Fe-TPPCN, which was ascribed to the

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1s→4pz transition with simultaneous ligand-to-metal charge transfer, further confirming that the

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FeSAs/PTFs samples contain square-planar Fe-N4 porphyrin-like structure with D4h symmetry.47

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The high-resolution N 1s peak at 400.1 eV in XPS result also demonstrated the presence of Fe-N

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bonds (Figure S3). Meanwhile, FeSAs/PTF-400 has an E0 value (the first inflection point) of

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7132.1 eV, which is very close to that of the precursor Fe-TPPCN reference, indicating the

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predominance of Fe3+ in this sample. In comparison, FeSAs/PTF-600 has an E0 value of 7130.6

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eV, very close to the Fe foil sample, suggesting that the mainly Fe species was Fe2+.29-34 This

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was also verified by the X-ray photoelectron spectroscopy (XPS) measurements (Figure 5b). For

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FeSAs/PTF-400, the peaks at the binding energies of 711.4 eV (Fe 2p3/2) and 724.5 eV (Fe 2p1/2)

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are attributed to Fe3+ species and are in consistent with the XANES results. In comparison, the

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higher ratio of the areas of 709.6 eV in FeSAs/PTF-600 indicated that Fe2+ species predominated

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in this sample.30 As shown in the Fe K-edge EXAFS curves (Figure 5c), no obvious peak at the

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position of Fe-Fe coordination was observed in all the three FeSAs/PTFs samples and the

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monomer Fe-TPPCN, which was different from that of Fe foil. These results suggested that no

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Fe-based particle was formed and all the Fe sites are in an atomically dispersed form, which was

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in consistent with the above HAADF-STEM results. Furthermore, FeSAs/PTF-400 sample

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shows an obvious signal at 1.59 Å related to Fe-N coordination in the first shell,48 which was

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similar to that of the precursor Fe-TPPCN reference sample. This result suggested that the Fe

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center in FeSAs/PTF-400 may be coordinated with four nitrogen atoms and one chlorine atom in

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the axial direction perpendicular to the Fe-N4 plane, which was also confirmed by the presence

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of chlorine element (Figure S11) and Ferric based on XPS (Figure 5b). Notably, the

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corresponding R values in FeSAs/PTF-500 and FeSAs/PTF-600 shift to 1.47 Å and 1.44 Å,

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respectively, which was consistent with other reported Fe-N species scattering paths.29-34 The Fe-

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N coordination peak shifts to a low R-position with the increase of ionothermal temperature,

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which may be resulted from their different coordination models. The coordination model varies

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because partial of Fe3+ or almost of Fe3+ atoms were reduce to Fe2+ (Figure 5b) at high

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temperature by the in situ produced graphitized carbon (Figure 1a and 1b), thus forming Fe-N4

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coordination configuration in FeSAs/PTF-x (x = 500, 600) samples, which is beneficial for the

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coordination and activation of O2.29-31 In order to prove our hypothesis, these two kinds of

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coordination models (Fe-N4Cl and Fe-N4) were used for EXAFS fitting of Fe-TPPCN and

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FeSAs/PTF, respectively. As shown in Figure 5d-f, the fitting curves were almost identical with

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the measured data and the fitting parameters given in Table S6 were quite good. In addition, the

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EXAFS fitting results revealed that the Fe-N coordination numbers of FeSAs/PTF-400 and

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FeSAs/PTF-600 are 4.17 and 3.98, respectively (Table S6). It suggested that the Fe porphyrin-

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like structure was still retained even synthesized at 600 oC. Thus, the prominent ORR

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performance of FeSAs/PTF-600 is suggested to be come from the unique porphyrin-like

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architectures, the compositional features of the catalyst including high density and uniform

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distribution of the Fe-N4 active sites, the highly hierarchical porosity, high conductivity and the

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superstable triazine-based framework.

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In conclusion, highly stable atomically dispersed Fe-N4 species embedded in porous

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porphyrinic triazine-based frameworks (FeSAs/PTF-600) were rationally designed and fabricated

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by using one-step ionothermal synthesis approach. The unique iron single-atoms with Fe-N4

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configuration were unambiguously identified by spherical aberration-corrected transmission

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electron microscope observation and X-ray absorption fine structure analyses. The resulting

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FeSAs/PTF-600 exhibits excellent ORR activity, long-term durability and good methanol

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tolerance in both alkaline and acidic media, which was attributed to the high porosity, abundant

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atomically dispersed Fe-N4 species, high electrical conductivity, and the superstable triazine-

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based network. The control experiments associated with poisoning tests confirmed that the main

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active site originated from Fe-N4 with metalporphyrin-like structure. The current study highlights

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the great advantages in the fabrication of single metal atom catalysts based on porous covalent

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triazine-based frameworks systems. This work presented here paves an avenue to design and

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preparation of stable non-precious metal single-atom stabilized by CTFs toward diverse

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electrocatalytic applications, such as ORR, hydrogen evolution reaction (HER) and CO2

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reduction.

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ASSOCIATED CONTENT

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Supporting Information.

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Experimental details; electrocatalytic measurements details; FT-IR spectra, TGA, ICP, EA

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results of catalysts; Rct values of catalysts; pore size distribution of catalysts; TEM and HAAD-

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STEM images of catalysts; H2O2 yield of catalysts in 0.1 M HClO4; methanol-crossover effect

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test of FeSAs/PTF-600 and Pt/C in 0.1 M HClO4; table of comparison of ORR performance

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between FeSAs/PTF-600 and other reported catalysts; EXAFS data fitting results of samples.

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AUTHOR INFORMATION

5

*Email: [email protected]

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*Email: [email protected]

7

Notes

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The authors declare no competing financial interest.

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ACKNOWLEDGMENT

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We acknowledge the financial support from the 973 Program (2014CB845605), Strategic

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Priority Research Program of the Chinese Academy of Sciences (XDB20000000), NSFC

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(21671188, 21521061, and 21331006), Key Research Program of Frontier Science, CAS

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(QYZDJ-SSW-SLH045), Youth Innovation Promotion Association, CAS (2014265). We thank

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the beamline BL14W1 station for XAFS measurements at the Shanghai Synchrotron Radiation

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Facility, China.

16

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Scheme 1. Schematic illustration of the formation of FeSAs/PTF. 47x15mm (300 x 300 DPI)

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Figure 1. a) PXRD patterns and b) Raman spectra of FeSAs/PTF-400, 500, 600. c) Nyquist plots of different samples over the frequency range from 100 kHz to 10 mHz. d) N2 adsorption-desorption isotherms of FeSAs/PTFs. 64x48mm (300 x 300 DPI)

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Figure 2. a) TEM image of FeSAs/PTF-600. b) Corresponding EDS mapping reveals the homogeneous distribution of Fe, C, and N elements. c, d) HAADF-STEM images and enlarged images of FeSAs/PTF-600. Part of single Fe atoms highlighted by red circles. 82x82mm (300 x 300 DPI)

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Figure 3. Electrochemical evaluation of catalysts in alkaline media. a) Linear sweep voltammograms (LSVs) of FeSAs/PTF-400, 500, 600 and Pt/C at 1600 rpm in O2-saturated 0.1 M KOH (scan rate: 10 mV s-1). b) LSVs of FeSAs/PTF-600 at different rotation speeds (inset: K-L plots and electron transfer numbers). c) Corresponding Tafel plots obtained from the RDE polarization curves. d) Electron transfer number of different samples obtained from the RRDE curves. e) Methanol-crossover effects test of FeSAs/PTF-600 and Pt/C. f) Current-time chronoamperometry for FeSAs/PTF-600 and Pt/C in an O2-saturated 0.1 M KOH solution. g) LSVs of FeSAs/PTF-600, FeNPs/PTF-600 and PTF-600 without metal loaded. h) LSVs of FeSAs/PTF-600 before and after the addition of 0.1M NaSCN in 0.1 M KOH. i) LSVs of poisoned FeSAs/PTF600 in 0.1 M KOH. 116x87mm (300 x 300 DPI)

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Figure 4. Electrochemical evaluation of catalysts in acidic media. a) LSVs of FeSAs/PTF-400, 500, 600 and Pt/C at 1600 rpm in O2-saturated 0.1 M HClO4 (scan rate: 10 mV s-1). b) Corresponding Tafel plots obtained from the RDE polarization curves. c) Electron transfer number of different samples obtained by RRDE. d) Current-time chronoamperometry for FeSAs/PTF-600 and Pt/C in an O2-saturated 0.1 M HClO4 solution. 61x46mm (300 x 300 DPI)

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Figure 5. a) The normalized Fe K-edge XANES spectra of the FeSAs/PTFs, Fe-TPPCN and Fe foil. b) XPS spectra of the Fe 2p region of FeSAs/PTF-400, 500, 600. c) Fourier transform EXAFS spectra of different samples. The corresponding EXAFS fitting curves of d) Fe-TPPCN, e) FeSAs/PTF-400 and f) FeSAs/PTF-600.

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