Recent advances in Fe-N-C single-atom site coupled synergistic catalysts for boosting oxygen reduction reaction

Katam Srinivas , Zhuo Chen , Hesheng Yu , Dawei Liu , Jian Zhen Ou , Ming‐qiang Zhu , Yuanfu Chen

Electron ›› 2024, Vol. 2 ›› Issue (1) : 26

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Electron ›› 2024, Vol. 2 ›› Issue (1) :26 DOI: 10.1002/elt2.26
REVIEW ARTICLE
Recent advances in Fe-N-C single-atom site coupled synergistic catalysts for boosting oxygen reduction reaction
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Abstract

Metal–air batteries, fuel cells, and electrochemical H2O2 production currently attract substantial consideration in the energy sector owing to their efficiency and eco-consciousness. However, their broader use is hindered by the complex oxygen reduction reaction (ORR) that occurs at cathodes and involves intricate electron transfers. Despite the significant ORR performance of platinum-based catalysts, their high cost, operational limitations, and susceptibility to methanol poisoning hinder broader implementation. This emphasizes the need for efficient nonprecious metal-based ORR electrocatalysts. A promising approach involves utilizing single-atom catalysts (SACs) featuring metal–nitrogen– carbon (M-N-C) coordination sites. SACs offer advantages such as optimal utilization of metal atoms, uniform active centers, precisely defined catalytic sites, and robust metal–support interactions. However, the symmetrical electron distribution around the central metal atom of a single-atom site (M-N4) often results in suboptimal ORR performance. This challenge can be addressed by carefully tailoring the surrounding environment of the active center. This review specifically focuses on recent advancements in the Fe-N4 environment within Fe-N-C SACs. It highlights the promising strategy of coupling Fe-N4 sites with metal clusters and/or nanoparticles, which enhances intrinsic activity. By capitalizing on the interplay between Fe-N4 sites and associated species, overall ORR performance improved. The review combines findings from experimental studies and density functional theory simulations, covering synthesis strategies for Fe-N-C coupled synergistic catalysts, characterization techniques, and the influence of associated particles on ORR activity. By offering a comprehensive outlook, the review aims to encourage research into high-efficiency Fe single-atom sites coupled synergistic catalysts for real-world applications in the coming years.

Keywords

electrocatalysis / oxygen reduction reaction / particle@Fe-N-C / single-atom catalysts / synergistic catalysts

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Katam Srinivas, Zhuo Chen, Hesheng Yu, Dawei Liu, Jian Zhen Ou, Ming‐qiang Zhu, Yuanfu Chen. Recent advances in Fe-N-C single-atom site coupled synergistic catalysts for boosting oxygen reduction reaction. Electron, 2024, 2(1): 26 DOI:10.1002/elt2.26

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

ChongL, WenJ, KubalJ, et al. Ultralow-loading platinumcobalt fuel cell catalysts derived from imidazolate frameworks. Science. 2018;362(6420):1276-1281.

[2]

XieX, HeC, LiB, et al. Performance enhancement and degradation mechanism identification of a single-atom Co–N–C catalyst for proton exchange membrane fuel cells. Nat Catal. 2020;3(12):1044-1054.

[3]

CuiT, WangY, YeT, et al. Engineering dual single-atom sites on 2D ultrathin N-doped carbon nanosheets attaining ultralow-temperature zinc-air battery. Angew Chem Int Ed. 2022;61(12):e202115219.

[4]

WuY, DingY, HanX, et al. Modulating coordination environment of Fe single atoms for high-efficiency all-PH-tolerated H2O2 electrochemical production. Appl Catal B Environ. 2022;315:121578.

[5]

ChenK-Y, HuangY-X, JinR-C, Huang B-C. Single atom catalysts for use in the selective production of hydrogen peroxide via two-electron oxygen reduction reaction: mechanism, activity, and structure optimization. Appl Catal B Environ. 2023;337:122987.

[6]

ZhouR, ZhengY, JaroniecM, Qiao S-Z. Determination of the electron transfer number for the oxygen reduction reaction: from theory to experiment. ACS Catal. 2016;6(7):4720-4728.

[7]

SinghSK, Takeyasu K, NakamuraJ. Active sites and mechanism of oxygen reduction reaction electrocatalysis on nitrogen-doped carbon materials. Adv Mater. 2019;31(13):1804297.

[8]

WanC, DuanX, HuangY. Molecular design of single-atom catalysts for oxygen reduction reaction. Adv Energy Mater. 2020;10(14):1903815.

[9]

YangX, ZengY, AlnoushW, Hou Y, HigginsD, WuG. Tuning two-electron oxygen-reduction pathways for H2O2 electrosynthesis via engineering atomically dispersed single metal site catalysts. Adv Mater. 2022;34(23):2107954.

[10]

LiuL, CormaA. Metal catalysts for heterogeneous catalysis: from single atoms to nanoclusters and nanoparticles. Chem Rev. 2018;118(10):4981-5079.

[11]

TuW, ChenK, ZhuL, et al. Tungsten-doping-induced surface reconstruction of porous ternary Pt-based alloy electrocatalyst for oxygen reduction. Adv Funct Mater. 2019;29(7):1807070.

[12]

HuangL, SuY, QiR, et al. Boosting oxygen reduction via integrated construction and synergistic catalysis of porous platinum alloy and defective graphitic carbon. Angew Chem Int Ed. 2021;60(48):25530-25537.

[13]

MatinMA, LeeJ, KimGW, et al. Morphing Mncore@Ptshell nanoparticles: effects of core structure on the ORR performance of Pt shell. Appl Catal B Environ. 2020;267:118727.

[14]

GuanJ, YangS, LiuT, et al. Intermetallic FePt@PtBi core–shell nanoparticles for oxygen reduction electrocatalysis. Angew Chem Int Ed. 2021;60(40):21899-21904.

[15]

SuiS, WangX, ZhouX, Su Y, RiffatS, LiuC. A comprehensive review of Pt electrocatalysts for the oxygen reduction reaction: nanostructure, activity, mechanism and carbon support in PEM fuel cells. J Mater Chem A. 2017;5(5):1808-1825.

[16]

WanK, ChuT, LiB, MingP, ZhangC. Rational design of atomically dispersed metal site electrocatalysts for oxygen reduction reaction. Adv Sci. 2023;10(11):2203391.

[17]

LiZ, XuS, ShiY, ZouX, WuH, LinS. Metal-semiconductor oxide (WO3@W) induces an efficient electro–photo synergistic catalysis for MOR and ORR. Chem Eng J. 2021;414:128814.

[18]

MoralesDM, Kazakova MA, DieckhöerS, et al. Trimetallic Mn-Fe-Ni oxide nanoparticles supported on multi-walled carbon nanotubes as high-performance bifunctional ORR/OER electrocatalyst in alkaline media. Adv Funct Mater. 2020;30(6):1905992.

[19]

WangW, ChenJ-Q, TaoY-R, Zhu S-N, ZhangY-X, WuX-C. Flowerlike Ag-supported Ce-doped Mn3O4 nanosheet heterostructure for a highly efficient oxygen reduction reaction: roles of metal oxides in Ag surface states. ACS Catal. 2019;9(4):3498-3510.

[20]

LianY, ShiK, YangH, et al. Elucidation of active sites on S, N codoped carbon cubes embedding Co–Fe carbides toward reversible oxygen conversion in high-performance zinc–air batteries. Small. 2020;16(23):1907368.

[21]

TanH, LiY, KimJ, et al. Sub-50 nm iron–nitrogen-doped hollow carbon sphere-encapsulated iron carbide nanoparticles as efficient oxygen reduction catalysts. Adv Sci. 2018;5(7):1800120.

[22]

WangY, LiuJ, LuT, HeR, XuN, QiaoJ. Ultra-high voltage efficiency rechargeable zinc-air battery based on high-performance structurally regulated metal-rich nickel phosphides and carbon hybrids bifunctional electrocatalysts. Appl Catal B Environ. 2023;321:122041.

[23]

GuoY, YuanP, ZhangJ, et al. Co2P-CoN double active centers confined in N-doped carbon nanotube: heterostructural engineering for trifunctional catalysis toward HER, ORR, OER, and Zn-air batteries driven water splitting. Adv Funct Mater. 2018;28(51):1805641.

[24]

ZhangC, LuR, LiuC, et al. Trimetallic sulfide hollow superstructures with engineered D-band center for oxygen reduction to hydrogen peroxide in alkaline solution. Adv Sci. 2022;9(12):2104768.

[25]

HanC, LiQ, WangD, Lu Q, XingZ, YangX. Cobalt sulfide nanowires core encapsulated by a N, S codoped graphitic carbon shell for efficient oxygen reduction reaction. Small. 2018;14(17):1703642.

[26]

BallP. Single-atom catalysis: a new field that learns from tradition. Natl Sci Rev. 2018;5(5):690-693.

[27]

HanX, LingX, WangY, et al. Generation of nanoparticle, atomic-cluster, and single-atom cobalt catalysts from zeolitic imidazole frameworks by spatial isolation and their use in zinc–air batteries. Angew Chem Int Ed. 2019;58(16):5359-5364.

[28]

ZhouX, MengR, ZhongN, Yin S, MaG, LiangX. Size-dependent cobalt catalyst for lithium sulfur batteries: from single atoms to nanoclusters and nanoparticles. Small Methods. 2021;5(10):2100571.

[29]

ParkJW, ParkG, KimM, et al. Ni-single atom decorated mesoporous carbon electrocatalysts for hydrogen evolution reaction. Chem Eng J. 2023;468:143733.

[30]

XieC, NiuZ, KimD, LiM, YangP. Surface and interface control in nanoparticle catalysis. Chem Rev. 2020;120(2):1184-1249.

[31]

HouC-C, WangH-F, LiC, XuQ. From metal–organic frameworks to single/dual-atom and cluster metal catalysts for energy applications. Energy Environ Sci. 2020;13(6):1658-1693.

[32]

YangJ, LiW, WangD, Li Y. Electronic metal–support interaction of single-atom catalysts and applications in electrocatalysis. Adv Mater. 2020;32(49):2003300.

[33]

MaschmeyerT, ReyF, SankarG, Thomas JM. Heterogeneous catalysts obtained by grafting metallocene complexes onto mesoporous silica. Nature. 1995;378(6553):159-162.

[34]

QiaoB, WangA, YangX, et al. Single-atom catalysis of CO oxidation using Pt1/FeOx. Nat Chem. 2011;3(8):634-641.

[35]

CaoL, LiuW, LuoQ, et al. Atomically dispersed iron hydroxide anchored on Pt for preferential oxidation of CO in H2. Nature. 2019;565(7741):631-635.

[36]

JiaoL, LiJ, RichardLL, et al. Chemical vapour deposition of Fe–N–C oxygen reduction catalysts with full utilization of dense Fe–N4 sites. Nat Mater. 2021;20(10):1385-1391.

[37]

ZengY, Almatrafi E, XiaW, et al. Nitrogen-doped carbon-based single-atom Fe catalysts: synthesis, properties, and applications in advanced oxidation processes. Coord Chem Rev. 2023;475:214874.

[38]

TongM, WangL, FuH. Designed synthesis and catalytic mechanisms of non-precious metal single-atom catalysts for oxygen reduction reaction. Small Methods. 2021;5(10):2100865.

[39]

WeiX, LuoX, WangH, et al. Highly-defective Fe-N-C catalysts towards PH-universal oxygen reduction reaction. Appl Catal B Environ. 2020;263:118347.

[40]

ZhuC, FuS, ShiQ, DuD, LinY. Single-atom electrocatalysts. Angew Chem Int Ed. 2017;56(45):13944-13960.

[41]

WangQ, YangY, SunF, et al. Molten NaCl-assisted synthesis of porous Fe-N-C electrocatalysts with a high density of catalytically accessible FeN4 active sites and outstanding oxygen reduction reaction performance. Adv Energy Mater. 2021;11(19):2100219.

[42]

SrinivasK, ChenZ, MaF, et al. Highly accessible atomically dispersed FeNx sites coupled with Fe3C@C core-shell nanoparticles boost the oxygen catalysis for ultra-stable rechargeable Zn-air batteries. Appl Catal B Environ. 2023;335:122887.

[43]

LiL, HuangB, TangX, et al. Recent developments of microenvironment engineering of single-atom catalysts for oxygen reduction toward desired activity and selectivity. Adv Funct Mater. 2021;31(45):2103857.

[44]

XiaoF, WangQ, XuG-L, et al. Atomically dispersed Pt and Fe sites and Pt–Fe nanoparticles for durable proton exchange membrane fuel cells. Nat Catal. 2022;5(6):503-512.

[45]

WaghNK, KimD-H, Kim S-H, ShindeSS, LeeJ-H. Heuristic iron–cobalt-mediated robust PH-universal oxygen bifunctional lusters for reversible aqueous and flexible solid-state Zn–air cells. ACS Nano. 2021;15(9):14683-14696.

[46]

GuoY, WangC, XiaoY, et al. Increasing the number of modulated Fe single-atom sites by adjacent nanoparticles for efficient oxygen reduction with spin-state transition. Nano Energy. 2023;117:108895.

[47]

LuoX, WeiX, WangH, et al. Secondary-atom-doping enables robust Fe–N–C single-atom catalysts with enhanced oxygen reduction reaction. Nano-Micro Lett. 2020;12(1):163.

[48]

ShangH, ZhouX, DongJ, et al. Engineering unsymmetrically coordinated Cu-S1N3 single atom sites with enhanced oxygen reduction activity. Nat Commun. 2020;11(1):3049.

[49]

PanY, ChenY, WuK, et al. Regulating the coordination structure of single-atom Fe-NxCy catalytic sites for benzene oxidation. Nat Commun. 2019;10(1):4290. https://doi.org/10.1038/s41467-019-12362-8
[50]

ChenY, JiS, ZhaoS, et al. Enhanced oxygen reduction with single-atomic-site iron catalysts for a zinc-air battery and hydrogen-air fuel cell. Nat Commun. 2018;9(1):5422.

[51]

ZhangJ, ZhaoY, ChenC, et al. Tuning the coordination environment in single-atom catalysts to achieve highly efficient oxygen reduction reactions. J Am Chem Soc. 2019;141(51):20118-20126.

[52]

ChengX, YangJ, YanW, et al. Nano-geometric deformation and synergistic Co nanoparticles—Co-N4 composite sites for proton exchange membrane fuel cells. Energy Environ Sci. 2021;14(11):5958-5967.

[53]

WanX, LiuQ, LiuJ, et al. Iron atom–cluster interactions increase activity and improve durability in Fe–N–C fuel cells. Nat Commun. 2022;13(1):2963.

[54]

WeiX, LuoX, WuN, GuW, LinY, ZhuC. Recent advances in synergistically enhanced single-atomic site catalysts for boosted oxygen reduction reaction. Nano Energy. 2021;84:105817.

[55]

LiY, ZhuX, LiL, et al. Study on the structure-activity relationship between single-atom, cluster and nanoparticle catalysts in a hierarchical structure for the oxygen reduction reaction. Small. 2022;18(7):2105487.

[56]

YangZ, ChenY, ZhangS, Zhang J. Identification and understanding of active sites of non-noble iron-nitrogencarbon catalysts for oxygen reduction electrocatalysis. Adv Funct Mater. 2023;33(26):2215185.

[57]

RongH, JiS, ZhangJ, Wang D, LiY. Synthetic strategies of supported atomic clusters for heterogeneous catalysis. Nat Commun. 2020;11(1):5884.

[58]

YanL, LiP, ZhuQ, et al. Atomically precise electrocatalysts for oxygen reduction reaction. Chem. 2023;9(2):280-342.

[59]

LiuH, YuF, WuK, et al. Recent progress on Fe-based single/dual-atom catalysts for Zn–air batteries. Small. 2022;18(43):2106635.

[60]

ZhangQ, LiuP, FuX, et al. Hierarchical architecture of well-aligned nanotubes supported bimetallic catalysis for efficient oxygen redox. Adv Funct Mater. 2022;32(22):2112805.

[61]

ZhaiW, HuangS, LuC, et al. Simultaneously integrate iron single atom and nanocluster triggered tandem effect for boosting oxygen electroreduction. Small. 2022;18(15):2107225.

[62]

YuanY, ZhangQ, YangL, et al. Facet strain strategy of atomically dispersed Fe-N-C catalyst for efficient oxygen electrocatalysis. Adv Funct Mater. 2022;32(36):2206081.

[63]

ZhangJ, DongX, XingW, et al. Engineering iron single atomic sites with adjacent ZrO2 nanoclusters via ligand–assisted strategy for effective oxygen reduction reaction and high–performance Zn–air batteries. Chem Eng J. 2021;420:129938.

[64]

ChenY, HeT, LiuQ, et al. Highly durable iron single-atom catalysts for low-temperature zinc-air batteries by electronic regulation of adjacent iron nanoclusters. Appl Catal B Environ. 2023;323:122163.

[65]

ZhangG, LiuX, YuP, et al. Fe3C coupled with Fe-nx supported on N-doped carbon as oxygen reduction catalyst for assembling Zn-air battery to drive water splitting. Chin Chem Lett. 2022;33(8):3903-3908.

[66]

JiaoL, ZhangR, WanG, et al. Nanocasting SiO2 into metal–organic frameworks imparts dual protection to high-loading Fe single-atom electrocatalysts. Nat Commun. 2020;11(1):2831.

[67]

LiF, NohH-J, CheW, et al. Tin nanoclusters confined in nitrogenated carbon for the oxygen reduction reaction. ACS Nano. 2022;16(11):18830-18837.

[68]

ZhaoD, ZhuangZ, CaoX, et al. Atomic site electrocatalysts for water splitting, oxygen reduction and selective oxidation. Chem Soc Rev. 2020;49(7):2215-2264.

[69]

JiS, ChenY, WangX, Zhang Z, WangD, LiY. Chemical synthesis of single atomic site catalysts. Chem Rev. 2020;120(21):11900-11955.

[70]

XuW, CaoM, LuoJ, et al. Research progress on single atom and particle synergistic catalysts for electrocatalytic reactions. Mater Chem Front. 2023;7(10):1992-2013.

[71]

JinH, ZhaoX, LiangL, et al. Sulfate ions induced concave porous S-N Co-doped carbon confined FeCx nanoclusters with Fe-N4 sites for efficient oxygen reduction in alkaline and acid media. Small. 2021;17(29):2101001.

[72]

PanY, MaX, WangM, et al. Construction of N, P Co-doped carbon frames anchored with Fe single atoms and Fe2P nanoparticles as a robust coupling catalyst for electrocatalytic oxygen reduction. Adv Mater. 2022;34(29):2203621.

[73]

HanA, SunW, WanX, et al. Construction of Co4 atomic clusters to enable Fe–N4 motifs with highly active and durable oxygen reduction performance. Angew Chem Int Ed. 2023;135:e202303185. https://doi.org/10.1002/ange.202303185
[74]

WangZ, JinX, XuR, et al. Cooperation between dual metal atoms and nanoclusters enhances activity and stability for oxygen reduction and evolution. ACS Nano. 2023;17(9):8622-8633.

[75]

HuangH, YuD, HuF, et al. Clusters induced electron redistribution to tune oxygen reduction activity of transition metal single-atom for metal–air batteries. Angew Chem Int Ed. 2022;61(12):e202116068.

[76]

ChenJ, HuangB, CaoR, et al. Steering local electronic configuration of Fe–N–C-based coupling catalysts via ligand engineering for efficient oxygen electroreduction. Adv Funct Mater. 2023;33(4):2209315.

[77]

YinS, YangJ, HanY, et al. Construction of highly active metal-containing nanoparticles and FeCo-N4 composite sites for the acidic oxygen reduction reaction. Angew Chem Int Ed. 2020;59(49):21976-21979.

[78]

YangQ, LiuR, PanY, et al. Ultrahigh-loaded Fe single atoms and Fe3C nanoparticle catalysts as air cathodes for highperformance Zn–air batteries. ACS Appl Mater Interfaces. 2023;15(4):5720-5731.

[79]

LiG, LiuJ, XuC, et al. Regulating the Fe-spin state by Fe/Fe3C neighbored single Fe-N4 sites in defective carbon promotes the oxygen reduction activity. Energy Storage Mater. 2023;56:394-402.

[80]

AoX, ZhangW, LiZ, et al. Markedly enhanced oxygen reduction activity of single-atom Fe catalysts via integration with Fe nanoclusters. ACS Nano. 2019;13(10):11853-11862.

[81]

WangH, YinF, LiuN, et al. Engineering Fe–Fe3C@Fe–N–C active sites and hybrid structures from dual metal–organic frameworks for oxygen reduction reaction in H2–O2 fuel cell and Li–O2 battery. Adv Funct Mater. 2019;29(23):1901531.

[82]

ZhaoS, LiJ, WangR, Cai J, ZangS. Electronically and geometrically modified single-atom Fe sites by adjacent Fe nanoparticles for enhanced oxygen reduction. Adv Mater. 2022;34(5):2107291.

[83]

XuC, GuoC, LiuJ, et al. Accelerating the oxygen adsorption kinetics to regulate the oxygen reduction catalysis via Fe3C nanoparticles coupled with single Fe-N4 sites. Energy Storage Mater. 2022;51:149-158.

[84]

KangG-S, JangJ-H, SonS-Y, et al. Fe-based non-noble metal catalysts with dual active sites of nanosized metal carbide and single-atomic species for oxygen reduction reaction. J Mater Chem A. 2020;8(42):22379-22388.

[85]

LiuM, LeeJ, YangT, et al. Synergies of Fe single atoms and clusters on N-doped carbon electrocatalyst for PH-universal oxygen reduction. Small Methods. 2021;5(5):2001165.

[86]

ChandrasekaranS, HuR, YaoL, et al. Mutual self-regulation of d-electrons of single atoms and adjacent nanoparticles for bifunctional oxygen electrocatalysis and rechargeable zincair batteries. Nano-Micro Lett. 2023;15(1):48.

[87]

LiH, DuK, XiangC, et al. Controlled chelation between tannic acid and Fe precursors to obtain N, S Co-doped carbon with high density Fe-single atom-nanoclusters for highly efficient oxygen reduction reaction in Zn–air batteries. J Mater Chem A. 2020;8(33):17136-17149.

[88]

LiH, ShuX, TongP, et al. Fe–Ni alloy nanoclusters anchored on carbon aerogels as high-efficiency oxygen electrocatalysts in rechargeable Zn–air batteries. Small. 2021;17(36):2102002.

[89]

WangY, QiaoM, MamatX. An advantage combined strategy for preparing Bi-functional electrocatalyst in rechargeable zinc-air batteries. Chem Eng J. 2020;402:126214.

[90]

HuS, NiW, YangD, et al. Fe3O4 nanoparticles encapsulated in single-atom Fe–N–C towards efficient oxygen reduction reaction: effect of the micro and macro pores. Carbon. 2020;162:245-255.

[91]

WeiX, SongS, WuN, et al. Synergistically enhanced singleatomic site Fe by Fe3C@C for boosted oxygen reduction in neutral electrolyte. Nano Energy. 2021;84:105840.

[92]

BaiJ, TangY, LinC, et al. Iron clusters regulate local charge distribution in Fe-N4 sites to boost oxygen electroreduction. J Colloid Interface Sci. 2023;648:440-447.

[93]

WangQ, LeiY, ChenZ, et al. Fe/Fe3C@C nanoparticles encapsulated in N-doped graphene–CNTs framework as an efficient bifunctional oxygen electrocatalyst for robust rechargeable Zn–air batteries. J Mater Chem A. 2018;6(2):516-526.

[94]

LiL, LiY, XiaoY, et al. Fe3O4-Encapsulating N-doped porous carbon materials as efficient oxygen reduction reaction electrocatalysts for Zn–air batteries. Chem Commun. 2019;55(52):7538-7541.

[95]

NiuW-J, YanY-Y, LiR-J, et al. Identifying the impact of Fe nanoparticles encapsulated by nitrogen-doped carbon to Fe single atom sites for boosting oxygen reduction reaction toward Zn-air batteries. Chem Eng J. 2023;456:140858.

[96]

CuiX, GaoL, LeiS, et al. Simultaneously crafting singleatomic Fe sites and graphitic layer-wrapped Fe3C nanoparticles encapsulated within mesoporous carbon tubes for oxygen reduction. Adv Funct Mater. 2021;31(10):2009197.

[97]

ZhangX, YuP, XingG, et al. Iron single atoms-assisted cobalt nitride nanoparticles to strengthen the cycle life of rechargeable Zn–air battery. Small. 2022;18(51):2205228.

[98]

YuQ, LianS, LiJ, et al. FeNx and γ-Fe2O3 Co-functionalized hollow graphitic carbon nanofibers for efficient oxygen reduction in an alkaline medium. J Mater Chem A. 2020;8(12):6076-6082.

[99]

LiB, IgawaK, ChaiJ, et al. String of pyrolyzed ZIF-67 particles on carbon fibers for high-performance electrocatalysis. Energy Storage Mater. 2020;25:137-144.

[100]

SunX, WeiP, GuS, et al. Atomic-level Fe-N-C coupled with Fe3C-Fe nanocomposites in carbon matrixes as high-efficiency bifunctional oxygen catalysts. Small. 2020;16(6):1906057.

[101]

JiangW, LiY, XuY, et al. Carbon nanotube-bridged N-doped mesoporous carbon nanosphere with atomic and nanoscaled M (M =Fe, Co) species for synergistically enhanced oxygen reduction reaction. Chem Eng J. 2021;421:129689.

[102]

LiuL, CormaA. Identification of the active sites in supported subnanometric metal catalysts. Nat Catal. 2021;4(6):453-456.

[103]

JiangW-J, GuL, LiL, et al. Understanding the high activity of Fe–N–C electrocatalysts in oxygen reduction: Fe/Fe3C nanoparticles boost the activity of Fe–nx. J Am Chem Soc. 2016;138(10):3570-3578.

[104]

ZhaoD, YuK, SongP, et al. Atomic-level engineering Fe1N2O2 interfacial structure derived from oxygen-abundant metal–organic frameworks to promote electrochemical CO2 reduction. Energy Environ Sci. 2022;15(9):3795-3804.

[105]

JinH, LiP, CuiP, et al. Unprecedentedly high activity and selectivity for hydrogenation of nitroarenes with single atomic Co1-N3P1 sites. Nat Commun. 2022;13(1):723.

[106]

ChangJ, ZhangQ, YuJ, et al. A Fe single atom seed-mediated strategy toward Fe3C/Fe-N-C catalysts with outstanding bifunctional ORR/OER activities. Adv Sci. 2023:2301656.

[107]

ZhangZ, SunJ, WangF, Dai L. Efficient oxygen reduction reaction (ORR) catalysts based on single iron atoms dispersed on a hierarchically structured porous carbon framework. Angew Chem Int Ed. 2018;57(29):9038-9043.

[108]

ShaoC, WuL, ZhangH, et al. A versatile approach to boost oxygen reduction of Fe-N4 sites by controllably incorporating sulfur functionality. Adv Funct Mater. 2021;31(25):2100833.

[109]

YuanK, Lützenkirchen-Hecht D, LiL, et al. Boosting oxygen reduction of single iron active sites via geometric and electronic engineering: nitrogen and phosphorus dual coordination. J Am Chem Soc. 2020;142(5):2404-2412.

[110]

HanY, WangY, XuR, et al. Electronic structure engineering to boost oxygen reduction activity by controlling the coordination of the central metal. Energy Environ Sci. 2018;11(9):2348-2352.

[111]

ChenG, LiuP, LiaoZ, et al. Zinc-mediated template synthesis of Fe-N-C electrocatalysts with densely accessible Fe-nx active sites for efficient oxygen reduction. Adv Mater. 2020;32(8):1907399.

[112]

ZhangY, WenZ, LiJ, YangCC, JiangQ. Coordination environment engineering of single-atom catalysts for the oxygen reduction reaction. Mater Chem Front. 2023;7:3595-3624.

[113]

SarmaBB, MaurerF, DoronkinDE, Grunwaldt J-D. Design of single-atom catalysts and tracking their fate using operando and advanced X-ray spectroscopic tools. Chem Rev. 2023;123(1):379-444.

[114]

LiuM, LiN, CaoS, et al. A “pre-constrained metal twins”strategy to prepare efficient dual-metal-atom catalysts for cooperative oxygen electrocatalysis. Adv Mater. 2022;34(7):2107421.

[115]

LiY, ZhangP, WanL, et al. A general carboxylate-assisted approach to boost the ORR performance of ZIF-derived Fe/N/C catalysts for proton exchange membrane fuel cells. Adv Funct Mater. 2021;31(15):2009645.

[116]

SrinivasK, LiuD, MaF, et al. Defect-engineered mesoporous undoped carbon nanoribbons for benchmark oxygen reduction reaction. Small. 2023:2301589. https://doi.org/10.1002/smll.202301589
[117]

WeiX, SongS, CaiW, et al. Tuning the spin state of Fe single atoms by Pd nanoclusters enables robust oxygen reduction with dissociative pathway. Chem. 2023;9(1):181-197.

[118]

LiuL, LiaoY, YueS, et al. Hierarchal porous graphenestructured electrocatalysts with Fe–N5 active sites modified with Fe clusters for enhanced performance toward oxygen reduction reaction. ACS Appl Mater Interfaces. 2022;14(37):42038-42047.

[119]

ChenZ, GaoX, WeiX, et al. Directly anchoring Fe3C nanoclusters and FeNx sites in ordered mesoporous nitrogendoped graphitic carbons to boost electrocatalytic oxygen reduction. Carbon. 2017;121:143-153.

[120]

LeiY, YangF, XieH, et al. Biomass in situ conversion to Fe single atomic sites coupled with Fe2O3 clusters embedded in porous carbons for the oxygen reduction reaction. J Mater Chem A. 2020;8(39):20629-20636.

[121]

XuL, TianY, DengD, et al. Cu nanoclusters/FeN4 amorphous composites with dual active sites in N-doped graphene for high-performance Zn–air batteries. ACS Appl Mater Interfaces. 2020;12(28):31340-31350.

[122]

XieQ, PanM, WangZ, et al. Enhancing the oxygen reduction activity by constructing nanocluster-scaled Fe2O3/Cu interfaces. Nanoscale. 2023;15(9):4388-4396.

[123]

LiuD, WangB, SrinivasK, et al. Rich and uncovered FeNx atom clusters anchored on nitrogen-doped graphene nanosheets for highly efficient and stable oxygen reduction reaction. J Alloys Compd. 2022;901:163763.

[124]

LiJ, Sougrati MT, ZitoloA, et al. Identification of durable and non-durable FeNx sites in Fe–N–C materials for proton exchange membrane fuel cells. Nat Catal. 2020;4(1):10-19.

[125]

YeW, ChenS, LinY, et al. Precisely tuning the number of Fe atoms in clusters on N-doped carbon toward acidic oxygen reduction reaction. Chem. 2019;5(11):2865-2878.

[126]

QinY, ChaoL, HeJJ, et al. Pt nanoparticle and Fe,N-codoped 3D graphene as synergistic electrocatalyst for oxygen reduction reaction. J Power Sources. 2016;335:31-37.

[127]

LiuS, MeyerQ, LiY, et al. Fe–N–C/Fe nanoparticle composite catalysts for the oxygen reduction reaction in proton exchange membrane fuel cells. Chem Commun. 2022;58(14):2323-2326.

[128]

ZhangZ, WangT, WangW, et al. A stable imide-linked metalphthalocyanine framework with atomically dispersed Fe-N4 sites and ultrafine nickel oxide nanoparticles to boost reversible oxygen electrocatalysis with a record-low ΔE of 0.59 V. Adv Energy Mater. 2023;13:2300325.

[129]

WangR, ZhangL, ShanJ, et al. Tuning Fe spin moment in Fe–N–C catalysts to climb the activity volcano via a local geometric distortion strategy. Adv Sci. 2022;9(31):2203917.

[130]

XieH, XieX, HuG, et al. Ta–TiOx nanoparticles as radical scavengers to improve the durability of Fe–N–C oxygen reduction catalysts. Nat Energy. 2022;7(3):281-289.

[131]

YangX, WangY, ZhangG, et al. SiO2-Fe/N/C catalyst with enhanced mass transport in PEM fuel cells. Appl Catal B Environ. 2020;264:118523.

[132]

XiaoZ, WuY, CaoS, et al. An active site pre-anchoring and post-exposure strategy in Fe(CN)64-@PPy derived Fe/S/Ndoped carbon electrocatalyst for high performance oxygen reduction reaction and zinc-air batteries. Chem Eng J. 2021;413:127395.

[133]

ZhouF, YuP, SunF, ZhangG, LiuX, WangL. The cooperation of Fe3C nanoparticles with isolated single iron atoms to boost the oxygen reduction reaction for Zn–air batteries. J Mater Chem A. 2021;9(11):6831-6840.

[134]

LiuD, Srinivas K, MaF, et al. Fe species anchored N, S-doped carbon as nonprecious catalyst for boosting oxygen reduction reaction. J Alloys Compd. 2023;937:168496.

[135]

GuoJ, ChengY, XiangZ. Confined-space-assisted preparation of Fe3O4-nanoparticle-modified Fe–N–C catalysts derived from a covalent organic polymer for oxygen reduction. ACS Sustainable Chem Eng. 2017;5(9):7871-7877.

[136]

ZhangC, WangX, SongK, et al. Engineering adjacent Fe3C as proton-feeding centers to single Fe sites enabling boosted oxygen reduction reaction kinetics for robust Zn-air batteries at high current densities. Nano Res. 2023:1-8. https://doi.org/10.1007/s12274-023-5578-1
[137]

ChenM-T, HuangZ-X, YeX, ZhangL, FengJ-J, Wang A-J. Caffeine derived graphene-wrapped Fe3C nanoparticles entrapped in hierarchically porous Fe-N-C nanosheets for boosting oxygen reduction reaction. J Colloid Interface Sci. 2023;637:216-224.

[138]

XieT, HuJ, XuQ, ZhouC. Metal-organic framework derived Fe3C nanoparticles coupled single-atomic iron for boosting oxygen reduction reaction. J Colloid Interface Sci. 2023;630:688-697.

[139]

JiD, PengS, LuJ, et al. Design and synthesis of porous channelrich carbon nanofibers for self-standing oxygen reduction reaction and hydrogen evolution reaction bifunctional catalysts in alkaline medium. J Mater Chem A. 2017;5(16):7507-7515.

[140]

YangZK, ZhaoZ-W, LiangK, et al. Synthesis of nanoporous structured iron carbide/Fe–N–carbon composites for efficient oxygen reduction reaction in Zn–air batteries. J Mater Chem A. 2016;4(48):19037-19044.

[141]

KimJH, SaYJ, JeongHY, Joo SH. Roles of Fe–Nx and Fe–Fe3C@C species in Fe–N/C electrocatalysts for oxygen reduction reaction. ACS Appl Mater Interfaces. 2017;9(11):9567-9575.

[142]

LiH, ChenX, ChenJ, Shen K, LiY. Hierarchically porous Fe, N-doped carbon nanorods derived from 1D Fe-doped MOFs as highly efficient oxygen reduction electrocatalysts in both alkaline and acidic media. Nanoscale. 2021;13(23):10500-10508.

[143]

LiN, LiuL, WangK, et al. Gelatin-derived 1D carbon nanofiber architecture with simultaneous decoration of single Fe–Nx sites and Fe/Fe3C nanoparticles for efficient oxygen reduction. Chem Eur J. 2021;27(42):10987-10997.

[144]

KimS-J, Mahmood J, KimC, et al. Defect-free encapsulation of Fe0 in 2D fused organic networks as a durable oxygen reduction electrocatalyst. J Am Chem Soc. 2018;140(5):1737-1742.

[145]

ZhuW, PeiY, DouglinJC, et al. Multi-scale study on bifunctional Co/Fe–N–C cathode catalyst layers with high active site density for the oxygen reduction reaction. Appl Catal B Environ. 2021;299(August):120656.

[146]

LiuB, WangS, FengR, Ni Y, SongF, LiuQ. Anchoring bimetal single atoms and alloys on N-Doping-Carbon nanofiber networks for an efficient oxygen reduction reaction and zinc–air batteries. ACS Appl Mater Interfaces. 2022;14(34):38739-38749.

[147]

QiaoZ, WangC, LiC, et al. Atomically dispersed single iron sites for promoting Pt and Pt3Co fuel cell catalysts: performance and durability improvements. Energy Environ Sci. 2021;14(9):4948-4960.

[148]

ChenZ, LiuR, LiuS, et al. FeS/FeNC decorated N,S-Codoped porous carbon for enhanced ORR activity in alkaline media. Chem Commun. 2020;56(85):12921-12924.

[149]

CaoY, ZhangY, YangL, et al. Boosting oxygen reduction reaction kinetics through perturbating electronic structure of single-atom Fe-N3S1 catalyst with sub-nano FeS cluster. J Colloid Interface Sci. 2023;650:924-933.

[150]

XuH, WangD, YangP, et al. FeS encapsulated hierarchical porous S, N-Dual-Doped carbon for oxygen reduction reaction facilitation in Zn–air batteries. Sustain Energy Fuels. 2021;5(10):2695-2703.

[151]

LiZ, WangW, ZhouM, et al. In-situ self-templated preparation of porous core–shell Fe1–xS@N, S Co-doped carbon architecture for highly efficient oxygen reduction reaction. J Energy Chem. 2021;54:310-317.

[152]

ZhangW, FanK, ChuangC-H, et al. Molten salt assisted fabrication of Fe@FeSA-N-C oxygen electrocatalyst for high performance Zn-air battery. J Energy Chem. 2021;61:612-621.

[153]

WangT, WangJ, WangX, Yang J, LiuJ, XuH. Graphenetemplated synthesis of sandwich-like porous carbon nanosheets for efficient oxygen reduction reaction in both alkaline and acidic media. Sci China Mater. 2018;61(7):915-925.

[154]

NajamT, ShahSSA, JavedMS, et al. Modulating the electronic structure of zinc single atom catalyst by P/N coordination and Co2P supports for efficient oxygen reduction in Zn-air battery. Chem Eng J. 2022;440:135928.

[155]

YangS, TakYJ, KimJ, SoonA, LeeH. Support effects in singleatom platinum catalysts for electrochemical oxygen reduction. ACS Catal. 2017;7(2):1301-1307.

[156]

ChangT-Y, TanakaY, IshikawaR, et al. Direct imaging of Pt single atoms adsorbed on TiO2 (110) surfaces. Nano Lett. 2014;14(1):134-138.

[157]

DuanS, WangR, LiuJ. Stability investigation of a high number density Pt1/Fe2O3 single-atom catalyst under different gas environments by HAADF-STEM. Nanotechnology. 2018;29(20):204002.

[158]

SahooSK, YeY, LeeS, et al. Rational design of TiC-supported single-atom electrocatalysts for hydrogen evolution and selective oxygen reduction reactions. ACS Energy Lett. 2019;4(1):126-132.

[159]

WanJ, ChenW, JiaC, et al. Defect effects on TiO2 nanosheets: stabilizing single atomic site Au and promoting catalytic properties. Adv Mater. 2018;30(11):1705369.

[160]

JiaoL, WanG, ZhangR, Zhou H, YuS, JiangH. From metal–organic frameworks to single-atom Fe implanted N-doped porous carbons: efficient oxygen reduction in both alkaline and acidic media. Angew Chem Int Ed. 2018;57(28):8525-8529.

[161]

HanY, WeiQ, FuY, et al. Microwave-assisted synthesis of highly active single-atom Fe/N/C catalysts for high-performance aqueous and flexible all-solid-state Zn-air batteries. Small. 2023;19(32):1-8.

[162]

KuY-P, Ehelebe K, HutzlerA, et al. Oxygen reduction reaction in alkaline media causes iron leaching from Fe–N–C electrocatalysts. J Am Chem Soc. 2022;144(22):9753-9763.

[163]

ChengN, ZhangL, Doyle-DavisK, SunX. Single-atom catalysts: from design to application. Electrochem Energy Rev. 2019;2(4):539-573.

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