Recent progress on mechanisms, principles, and strategies for high-activity and high-stability non-PGM fuel cell catalyst design

Yuping Yuan; Yun Zheng; Dan Luo; Weibin Qiu; Jiantao Wang; Xin Wang; Zhongwei Chen

doi:10.1002/cey2.426

Carbon Energy ›› 2024, Vol. 6 ›› Issue (5) : 426 DOI: 10.1002/cey2.426

REVIEW

Recent progress on mechanisms, principles, and strategies for high-activity and high-stability non-PGM fuel cell catalyst design

Author information +

History +

PDF

Abstract

The commercialization of a polymer membrane H₂–O₂ fuel cell and its widespread use call for the development of cost-effective oxygen reduction reaction (ORR) nonplatinum group metal (NPGM) catalysts. Nevertheless, to meet the requests for the real-world fuel cell application and replacing platinum catalysts, it still needs to address some challenges for NPGM catalysts regarding the sluggish ORR kinetics in the cathode and their poor durability in acidic environment. In response to these issues, numerous efforts have been made to study NPGM catalysts both theoretically and experimentally, developed these into the atomically dispersed coordinated metal–nitrogen–carbon (M–N–C) form over the past decades. In this review, we present a comprehensive summary of recent advancements on NPGM catalysts with high activity and durability. Catalyst design strategies in terms of optimizing active-site density and enhancing catalyst stability against demetalization and carbon corrosion are highlighted. It is also emphasized the importance of understanding the mechanisms and principles behind those strategies through a combination of theoretical modeling and experimental work. Especially, further understanding the mechanisms related to the active-site structure and the formation process of the single-atom active site under pyrolysis conditions is critical for active-site engineering. Optimizing the active-site distance is the basic principle for improving catalyst activity through increasing the catalyst active-site density. Theoretical studies for the catalyst deactivation mechanism and modeling stable active-site structures provide both mechanisms and principles to improve the NPGM catalyst durability. Finally, currently remained challenges and perspectives in the future on designing high-performance atomically dispersed NPGM catalysts toward fuel cell application are discussed.

Keywords

batteries / electrocatalysis / energy storage and conversion / fuel cells

Cite this article

Download citation ▾

Yuping Yuan, Yun Zheng, Dan Luo, Weibin Qiu, Jiantao Wang, Xin Wang, Zhongwei Chen. Recent progress on mechanisms, principles, and strategies for high-activity and high-stability non-PGM fuel cell catalyst design. Carbon Energy, 2024, 6(5): 426 DOI:10.1002/cey2.426

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Fan J, Chen M, Zhao Z, et al. Bridging the gap between highly active oxygen reduction reaction catalysts and effective catalyst layers for proton exchange membrane fuel cells. Nat Energy. 2021; 6 (5): 475- 486.

[2]	Kodama K, Nagai T, Kuwaki A, Jinnouchi R, Morimoto Y. Challenges in applying highly active Pt-based nanostructured catalysts for oxygen reduction reactions to fuel cell vehicles. Nat Nanotechnol. 2021; 16 (2): 140- 147.

[3]	Jiao K, Xuan J, Du Q, et al. Designing the next generation of proton-exchange membrane fuel cell. Nature. 2021; 595 (7867): 361- 369.

[4]	Thompson ST, Papageorgopoulos D. Platinum group metal-free catalysts boost cost competitiveness of fuel cell vehicles. Nat Catal. 2019; 2 (7): 558- 561.

[5]	Wang XX, Swihart MT, Wu G. Achievements, challenges and perspectives on cathode catalysts in proton exchange membrane fuel cells for transportation. Nat Catal. 2019; 2 (7): 578- 589.

[6]	Adabi H, Shakouri A, Ul Hassan N, et al. High-performing commercial Fe-N-C cathode electrocatalyst for anion-exchange membrane fuel cells. Nat Energy. 2021; 6 (8): 834- 843.

[7]	Luo E, Chu Y, Liu J, et al. Pyrolyzed M-N_x catalysts for oxygen reduction reaction: progress and prospects. Energy Environ Sci. 2021; 14 (4): 2158- 2185.

[8]	Martinez U, Komini Babu S, Holby EF, Chung HT, Yin X, Zelenay P. Progress in the development of Fe-based PGM-free electrocatalysts for the oxygen reduction reaction. Adv Mater. 2019; 31 (31): 1806545.

[9]	He Y, Liu S, Priest C, Shi Q, Wu G. Atomically dispersed metal-nitrogen-carbon catalysts for fuel cells: advances in catalyst design, electrode performance, and durability improvement. Chem Soc Rev. 2020; 49 (11): 3484- 3524.

[10]	Wang H, Liu D-J. Rational design of platinum-group-metal-free electrocatalysts for oxygen reduction reaction. Curr Opin Electrochem. 2021; 28: 100724.

[11]	Jasinski R. A new fuel cell cathode catalyst. Nature. 1964; 201 (4925): 1212- 1213.

[12]	Gupta S, Tryk D, Bae I, Aldred W, Yeager E. Heat-treated polyacrylonitrile-based catalysts for oxygen electroreduction. J Appl Electrochem. 1989; 19 (1): 19- 27.

[13]	Yeager E. Dioxygen electrocatalysis: mechanisms in relation to catalyst structure. J Mol Catal. 1986; 38 (1-2): 5- 25.

[14]	Zitolo A, Goellner V, Armel V, et al. Identification of catalytic sites for oxygen reduction in iron- and nitrogen-doped graphene materials. Nat Mater. 2015; 14 (9): 937- 942.

[15]	Zitolo A, Ranjbar-Sahraie N, Mineva T, et al. Identification of catalytic sites in cobalt-nitrogen-carbon materials for the oxygen reduction reaction. Nat Commun. 2017; 8: 957.

[16]	Luo F, Roy A, Silvioli L, et al. P-block single-metal-site tin/nitrogen-doped carbon fuel cell cathode catalyst for oxygen reduction reaction. Nat Mater. 2020; 19 (11): 1215- 1223.

[17]	Luo E, Zhang H, Wang X, et al. Single-atom Cr-N₄ sites designed for durable oxygen reduction catalysis in acid media. Angew Chem Int Ed. 2019; 58 (36): 12469- 12475.

[18]	Liu K, Fu J, Lin Y, et al. Insights into the activity of single-atom Fe-N-C catalysts for oxygen reduction reaction. Nat Commun. 2022; 13: 2075.

[19]	Zhang N, Zhou T, Chen M, et al. High-purity pyrrole-type FeN₄ sites as a superior oxygen reduction electrocatalyst. Energy Environ Sci. 2020; 13 (1): 111- 118.

[20]	Ramaswamy N, Tylus U, Jia Q, Mukerjee S. Activity descriptor identification for oxygen reduction on non-precious electrocatalysts: linking surface science to coordination chemistry. J Am Chem Soc. 2013; 135 (41): 15443- 15449.

[21]	Yuan S, Shui J-L, Grabstanowicz L, et al. A highly active and support-free oxygen reduction catalyst prepared from ultrahigh-surface-area porous polyporphyrin. Angew Chem Int Ed. 2013; 52 (32): 8349- 8353.

[22]	Wan X, Liu X, Li Y, et al. Fe-N-C electrocatalyst with dense active sites and efficient mass transport for high-performance proton exchange membrane fuel cells. Nat Catal. 2019; 2 (3): 259- 268.

[23]	Specchia S, Atanassov P, Zagal JH. Mapping transition metal-nitrogen-carbon catalyst performance on the critical descriptor diagram. Curr Opin Electrochem. 2021; 27: 100687.

[24]	Thompson ST, Wilson AR, Zelenay P, et al. ElectroCat: DOE's approach to PGM-free catalyst and electrode R&D. Solid State Ion. 2018; 319: 68- 76.

[25]	Lefèvre M, Proietti E, Jaouen F, Dodelet JP. Iron-based catalysts with improved oxygen reduction activity in polymer electrolyte fuel cells. Science. 2009; 324 (5923): 71- 74.

[26]	Proietti E, Jaouen F, Lefèvre M, et al. Iron-based cathode catalyst with enhanced power density in polymer electrolyte membrane fuel cells. Nat Commun. 2011; 2: 416.

[27]	Wu G, More KL, Johnston CM, Zelenay P. High-performance electrocatalysts for oxygen reduction derived from polyaniline, iron, and cobalt. Science. 2011; 332 (6028): 443- 447.

[28]	Mehmood A, Gong M, Jaouen F, et al. High loading of single atomic iron sites in Fe-NC oxygen reduction catalysts for proton exchange membrane fuel cells. Nat Catal. 2022; 5 (4): 311- 323.

[29]	Datye AK, Guo H. Single atom catalysis poised to transition from an academic curiosity to an industrially relevant technology. Nat Commun. 2021; 12: 895.

[30]	Li J, Gong J. Operando characterization techniques for electrocatalysis. Energy Environ Sci. 2020; 13 (11): 3748- 3779.

[31]	Zagal JH, Koper MTM. Reactivity descriptors for the activity of molecular MN₄ catalysts for the oxygen reduction reaction. Angew Chem Int Ed. 2016; 55 (47): 14510- 14521.

[32]	Li L, Huang B, Tang X, 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.

[33]	He J, Liu P, Ran R, Wang W, Zhou W, Shao Z. Single-atom catalysts for high-efficiency photocatalytic and photoelectrochemical water splitting: distinctive roles, unique fabrication methods and specific design strategies. J Mater Chem A. 2022; 10 (13): 6835- 6871.

[34]	Li J, Zhang H, Samarakoon W, et al. Thermally driven structure and performance evolution of atomically dispersed Fe-N₄ sites for oxygen reduction. Angew Chem Int Ed. 2019; 58 (52): 18971- 18980.

[35]	He Y, Shi Q, Shan W, et al. Dynamically unveiling metal-nitrogen coordination during thermal activation to design high-efficient atomically dispersed CoN₄ active sites. Angew Chem Int Ed. 2021; 60 (17): 9516- 9526.

[36]	Sun J, Jin J, Chang Y, Wang J, Zhang Q, Guo J. Unravelling temperature ramping rates in fabricating NaCl induced porous Co/N-C electrocatalysts for oxygen reduction reaction. ChemElectroChem. 2022; 9 (11): e202200375.

[37]	Huang Y, Chen Y, Xu M, et al. Catalysts by pyrolysis: direct observation of chemical and morphological transformations leading to transition metal-nitrogen-carbon materials. Mater Today. 2021; 47: 53- 68.

[38]	Chen Y, Huang Y, Xu M, et al. Catalysts by pyrolysis: direct observation of transformations during re-pyrolysis of transition metal-nitrogen-carbon materials leading to state-of-the-art platinum group metal-free electrocatalyst. Mater Today. 2022; 53: 58- 70.

[39]	Aiyappa HB, Wilde P, Quast T, et al. Oxygen evolution electrocatalysis of a single MOF-derived composite nanoparticle on the tip of a nanoelectrode. Angew Chem Int Ed. 2019; 58 (26): 8927- 8931.

[40]	Liu S, Li C, Zachman MJ, et al. Atomically dispersed iron sites with a nitrogen-carbon coating as highly active and durable oxygen reduction catalysts for fuel cells. Nat Energy. 2022; 7 (7): 652- 663.

[41]	Malko D, Kucernak A, Lopes T. In situ electrochemical quantification of active sites in Fe-N/C non-precious metal catalysts. Nat Commun. 2016; 7: 13285.

[42]	Sahraie NR, Kramm UI, Steinberg J, et al. Quantifying the density and utilization of active sites in non-precious metal oxygen electroreduction catalysts. Nat Commun. 2015; 6: 8618.

[43]	Primbs M, Sun Y, Roy A, et al. Establishing reactivity descriptors for platinum group metal (PGM)-free Fe-N-C catalysts for PEM fuel cells. Energy Environ Sci. 2020; 13 (8): 2480- 2500.

[44]	Zhang W, Chao Y, Zhang W, et al. Emerging dual-atomic-site catalysts for efficient energy catalysis. Adv Mater. 2021; 33 (36): 2102576.

[45]	Han A, Wang X, Tang K, et al. An adjacent atomic platinum site enables single-atom iron with high oxygen reduction reaction performance. Angew Chem Int Ed. 2021; 60 (35): 19262- 19271.

[46]	Xiao M, Chen Y, Zhu J, et al. Climbing the apex of the ORR volcano plot via binuclear site construction: electronic and geometric engineering. J Am Chem Soc. 2019; 141 (44): 17763- 17770.

[47]	Wan H, Østergaard TM, Arnarson L, Rossmeisl J. Climbing the 3D volcano for the oxygen reduction reaction using porphyrin motifs. ACS Sustainable Chem Eng. 2019; 7 (1): 611- 617.

[48]	Wan H, Jensen AW, Escudero-Escribano M, Rossmeisl J. Insights in the oxygen reduction reaction: from metallic electrocatalysts to diporphyrins. ACS Catal. 2020; 10 (11): 5979- 5989.

[49]	Sours T, Patel A, Nørskov J, Siahrostami S, Kulkarni A. Circumventing scaling relations in oxygen electrochemistry using metal-organic frameworks. J Phys Chem Lett. 2020; 11 (23): 10029- 10036.

[50]	Wellendorff J, Silbaugh TL, Garcia-Pintos D, et al. A benchmark database for adsorption bond energies to transition metal surfaces and comparison to selected DFT functionals. Surf Sci. 2015; 640: 36- 44.

[51]	Kunwar D, Zhou S, DeLaRiva A, et al. Stabilizing high metal loadings of thermally stable platinum single atoms on an industrial catalyst support. ACS Catal. 2019; 9 (5): 3978- 3990.

[52]	Li P, Jin Z, Qian Y, Fang Z, Xiao D, Yu G. Supramolecular confinement of single Cu atoms in hydrogel frameworks for oxygen reduction electrocatalysis with high atom utilization. Mater Today. 2020; 35: 78- 86.

[53]	Li P, Jin Z, Fang Z, Yu G. A surface-strained and geometry-tailored nanoreactor that promotes ammonia electrosynthesis. Angew Chem Int Ed. 2020; 59 (50): 22610- 22616.

[54]	Jin Z, Bard AJ. Surface interrogation of electrodeposited MnO_x and CaMnO₃ perovskites by scanning electrochemical microscopy: probing active sites and kinetics for the oxygen evolution reaction. Angew Chem Int Ed. 2021; 60 (2): 794- 799.

[55]	Li P, Jin Z, Qian Y, Fang Z, Xiao D, Yu G. Probing enhanced site activity of Co-Fe bimetallic sub-nanoclusters derived from dual cross-linked hydrogels for oxygen electrocatalysis. ACS Energy Lett. 2019; 4 (8): 1793- 1802.

[56]	Jin Z, Li P, Meng Y, Fang Z, Xiao D, Yu G. Understanding the inter-site distance effect in single-atom catalysts for oxygen electroreduction. Nat Catal. 2021; 4 (7): 615- 622.

[57]	Ma S, Goenaga GA, Call AV, Liu DJ. Cobalt imidazolate framework as precursor for oxygen reduction reaction electrocatalysts. Chem Eur J. 2011; 17 (7): 2063- 2067.

[58]	Lei H, Zhang Q, Liang Z, et al. Metal-corrole-based porous organic polymers for electrocatalytic oxygen reduction and evolution reactions. Angew Chem Int Ed. 2022; 61 (24): e202201104.

[59]	Lin Q, Bu X, Kong A, Mao C, Bu F, Feng P. Heterometal-embedded organic conjugate frameworks from alternating monomeric iron and cobalt metalloporphyrins and their application in design of porous carbon catalysts. Adv Mater. 2015; 27 (22): 3431- 3436.

[60]	Wang XX, Cullen DA, Pan Y-T, et al. Nitrogen-coordinated single cobalt atom catalysts for oxygen reduction in proton exchange membrane fuel cells. Adv Mater. 2018; 30 (11): 1706758.

[61]	Zhang H, Chung HT, Cullen DA, et al. High-performance fuel cell cathodes exclusively containing atomically dispersed iron active sites. Energy Environ Sci. 2019; 12 (8): 2548- 2558.

[62]	He Y, Hwang S, Cullen DA, et al. Highly active atomically dispersed CoN₄ fuel cell cathode catalysts derived from surfactant-assisted MOFs: carbon-shell confinement strategy. Energy Environ Sci. 2019; 12 (1): 250- 260.

[63]	Qu Y, Li Z, Chen W, et al. Direct transformation of bulk copper into copper single sites via emitting and trapping of atoms. Nat Catal. 2018; 1 (10): 781- 786.

[64]	Li J, Jiao L, Wegener E, et al. Evolution pathway from iron compounds to Fe₁(II)-N₄ sites through gas-phase iron during pyrolysis. J Am Chem Soc. 2020; 142 (3): 1417- 1423.

[65]	Li X, Yang X, Liu L, et al. Chemical vapor deposition for N/S-doped single Fe site catalysts for the oxygen reduction in direct methanol fuel cells. ACS Catal. 2021; 11 (12): 7450- 7459.

[66]	Jiao L, Li J, Richard LL, 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.

[67]	Wang Q, Ina T, Chen W-T, et al. Evolution of Zn(II) single atom catalyst sites during the pyrolysis-induced transformation of ZIF-8 to N-doped carbons. Sci Bull. 2020; 65 (20): 1743- 1751.

[68]	Menga D, Ruiz-Zepeda F, Moriau L, et al. Active-site imprinting: preparation of Fe-N-C catalysts from zinc ion-templated ionothermal nitrogen-doped carbons. Adv Energy Mater. 2019; 9 (43): 1902412.

[69]	Menga D, Low JL, Li Y-S, et al. Resolving the dilemma of Fe-N-C catalysts by the selective synthesis of tetrapyrrolic active sites via an imprinting strategy. J Am Chem Soc. 2021; 143 (43): 18010- 18019.

[70]	Wang Q, Yang Y, Sun F, 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.

[71]	Sun Y, Polani S, Luo F, Ott S, Strasser P, Dionigi F. Advancements in cathode catalyst and cathode layer design for proton exchange membrane fuel cells. Nat Commun. 2021; 12: 5984.

[72]	Du L, Zhang G, Liu X, et al. Biomass-derived nonprecious metal catalysts for oxygen reduction reaction: the demand-oriented engineering of active sites and structures. Carbon Energy. 2020; 2 (4): 561- 581.

[73]	Zhang J, Yang H, Gao J, et al. Design of hierarchical, three-dimensional free-standing single-atom electrode for H₂O₂ production in acidic media. Carbon Energy. 2020; 2 (2): 276- 282.

[74]	Fu X, Li N, Ren B, et al. Tailoring FeN₄ sites with edge enrichment for boosted oxygen reduction performance in proton exchange membrane fuel cell. Adv Energy Mater. 2019; 9 (11): 1803737.

[75]	Zhou Y, Chen G, Wang Q, et al. Fe-N-C electrocatalysts with densely accessible Fe-N₄ sites for efficient oxygen reduction reaction. Adv Funct Mater. 2021; 31 (34): 2102420.

[76]	Xia D, Yu C, Zhao Y, et al. Degradation and regeneration of Fe-N_x active sites for the oxygen reduction reaction: the role of surface oxidation, Fe demetallation and local carbon microporosity. Chem Sci. 2021; 12 (34): 11576- 11584.

[77]	Kumar K, Asset T, Li X, et al. Fe-N-C electrocatalysts' durability: effects of single atoms' mobility and clustering. ACS Catal. 2021; 11 (2): 484- 494.

[78]	Miner EM, Gul S, Ricke ND, et al. Mechanistic evidence for ligand-centered electrocatalytic oxygen reduction with the conductive MOF Ni₃(hexaiminotriphenylene)₂. ACS Catal. 2017; 7 (11): 7726- 7731.

[79]	Miner EM, Fukushima T, Sheberla D, Sun L, Surendranath Y, Dincă M. Electrochemical oxygen reduction catalysed by Ni₃(hexaiminotriphenylene)₂. Nat Commun. 2016; 7: 10942.

[80]	Sheberla D, Sun L, Blood-Forsythe MA, et al. High electrical conductivity in Ni₃(2,3,6,7,10,11-hexaiminotriphenylene)₂, a semiconducting metal−organic graphene analogue. J Am Chem Soc. 2014; 136 (25): 8859- 8862.

[81]	Chen T, Dou J-H, Yang L, et al. Continuous electrical conductivity variation in M₃(hexaiminotriphenylene)₂ (M = Co, Ni, Cu) MOF alloys. J Am Chem Soc. 2020; 142 (28): 12367- 12373.

[82]	Yue Y, Li H, Chen H, Huang N. Piperazine-linked covalent organic frameworks with high electrical conductivity. J Am Chem Soc. 2022; 144 (7): 2873- 2878.

[83]	Mariano RG, Wahab OJ, Rabinowitz JA, et al. Thousand-fold increase in O₂ electroreduction rates with conductive MOFs. ACS Cent Sci. 2022; 8 (7): 975- 982.

[84]	Li X, Liu Q, Yang B, Liao Z, Yan W, Xiang Z. An initial covalent organic polymer with closed-F edges directly for proton-exchange-membrane fuel cells. Adv Mater. 2022; 34 (36): 2204570.

[85]	Li X, Xiang Z. Identifying the impact of the covalent-bonded carbon matrix to FeN₄ sites for acidic oxygen reduction. Nat Commun. 2022; 13: 57.

[86]	Zhang J, Zhou Z, Wang F, Li Y, Jing Y. Two-dimensional metal hexahydroxybenzene frameworks as promising electrocatalysts for an oxygen reduction reaction. ACS Sustainable Chem Eng. 2020; 8 (19): 7472- 7479.

[87]	Iqbal R, Ali S, Yasin G, et al. A novel 2D Co₃(HADQ)₂ metal-organic framework as a highly active and stable electrocatalyst for acidic oxygen reduction. Chem Eng J. 2022; 430 (1): 132642.

[88]	Shao Y, Dodelet J-P, Wu G, Zelenay P. PGM-free cathode catalysts for PEM fuel cells: a mini-review on stability challenges. Adv Mater. 2019; 31 (31): 1807615.

[89]	Du L, Prabhakaran V, Xie X, Park S, Wang Y, Shao Y. Low-PGM and PGM-free catalysts for proton exchange membrane fuel cells: stability challenges and material solutions. Adv Mater. 2020; 33 (6): 1908232.

[90]	Ferrandon M, Wang X, Kropf AJ, et al. Stability of iron species in heat-treated polyaniline-iron-carbonpolymer electrolyte fuel cell cathode catalysts. Electrochim Acta. 2013; 110: 282- 291.

[91]	Banham D, Ye S, Pei K, Ozaki J, Kishimoto T, Imashiro Y. A review of the stability and durability of non-precious metal catalysts for the oxygen reduction reaction in proton exchange membrane fuel cells. J Power Sources. 2015; 285: 334- 348.

[92]	Choi CH, Baldizzone C, Grote J-P, Schuppert AK, Jaouen F, Mayrhofer KJJ. Stability of Fe-N-C catalysts in acidic medium studied by operando spectroscopy. Angew Chem Int Ed. 2015; 54 (43): 12753- 12757.

[93]	Choi CH, Baldizzone C, Polymeros G, et al. Minimizing operando demetallation of Fe-N-C electrocatalysts in acidic medium. ACS Catal. 2016; 6 (5): 3136- 3146.

[94]	Chenitz R, Kramm UI, Lefèvre M, et al. A specific demetalation of Fe-N₄ catalytic sites in the micropores of NC_Ar + NH₃ is at the origin of the initial activity loss of the highly active Fe/N/C catalyst used for the reduction of oxygen in PEM fuel cells. Energy Environ Sci. 2018; 11 (2): 365- 382.

[95]	Santori PG, Speck FD, Li J, et al. Effect of pyrolysis atmosphere and electrolyte pH on the oxygen reduction activity, stability and spectroscopic signature of FeN_x moieties in Fe-N-C catalysts. J Electrochem Soc. 2019; 166 (7): F3311- F3320.

[96]	Nabae Y, Yuan Q, Nagata S, et al. In situ X-ray absorption spectroscopy to monitor the degradation of Fe/N/C cathode catalyst in proton exchange membrane fuel cells. J Electrochem Soc. 2021; 168 (1): 014513.

[97]	Chen Z, Jiang S, Kang G, Nguyen D, Schatz GC, Van Duyne RP. Operando characterization of iron phthalocyanine deactivation during oxygen reduction reaction using electrochemical tip-enhanced Raman spectroscopy. J Am Chem Soc. 2019; 141 (39): 15684- 15692.

[98]	Seo MH, Higgins D, Jiang G, Choi SM, Han B, Chen Z. Theoretical insight into highly durable iron phthalocyanine derived non-precious catalysts for oxygen reduction reactions. J Mater Chem A. 2014; 2 (46): 19707- 19716.

[99]	Tang L, Han B, Persson K, et al. Electrochemical stability of nanometer-scale Pt particles in acidic environments. J Am Chem Soc. 2010; 132 (2): 596- 600.

[100]

Han B, Viswanathan V, Pitsch H. First-principles based analysis of the electrocatalytic activity of the unreconstructed Pt(100) surface for oxygen reduction reaction. J Phys Chem C. 2012; 116 (10): 6174- 6183.

[101]

Li Y, Wang N, Lei H, et al. Bioinspired N₄-metallomacrocycles for electrocatalytic oxygen reduction reaction. Coord Chem Rev. 2021; 442: 213996.

[102]

Wang J, Dou S, Wang X. Structural tuning of heterogeneous molecular catalysts for electrochemical energy conversion. Sci Adv. 2021; 7 (13): eabf3989.

[103]

Hong Y, Li L, Huang B, et al. Molecular control of carbon-based oxygen reduction electrocatalysts through metal macrocyclic complexes functionalization. Adv Energy Mater. 2021; 11 (33): 2100866.

[104]

Zhang W, Lai W, Cao R. Energy-related small molecule activation reactions: oxygen reduction and hydrogen and oxygen evolution reactions catalyzed by porphyrin- and corrole-based systems. Chem Rev. 2017; 117 (4): 3717- 3797.

[105]

Yan X, Jia Y, Wang K, et al. Controllable synthesis of Fe-N₄ species for acidic oxygen reduction. Carbon Energy. 2020; 2 (3): 452- 460.

[106]

Chung HT, Cullen DA, Higgins D, et al. Direct atomic-level insight into the active sites of a high-performance PGM-free ORR catalyst. Science. 2017; 357 (6350): 479- 484.

[107]

Marshall-Roth T, Libretto NJ, Wrobel AT, et al. A pyridinic Fe-N₄ macrocycle models the active sites in Fe/N-doped carbon electrocatalysts. Nat Commun. 2020; 11: 5283.

[108]

Ohyama J, Moriya M, Takahama R, et al. High durability of a 14-membered hexaaza macrocyclic Fe complex for an acidic oxygen reduction reaction revealed by in situ XAS analysis. JACS Au. 2021; 1 (10): 1798- 1804.

[109]

Moriya M, Takahama R, Kamoi K, et al. Fourteen-membered macrocyclic Fe complexes inspired by FeN₄-center-embedded graphene for oxygen reduction catalysis. J Phys Chem C. 2020; 124 (38): 20730- 20735.

[110]

Holby EF, Wang G, Zelenay P. Acid stability and demetalation of PGM-free ORR electrocatalyst structures from density functional theory: a model for “single-atom catalyst” dissolution. ACS Catal. 2020; 10 (24): 14527- 14539.

[111]

Patniboon T, Hansen HA. Acid-stable and active M-N-C catalysts for the oxygen reduction reaction: the role of local structure. ACS Catal. 2021; 11 (21): 13102- 13118.

[112]

Yang N, Peng L, Li L, et al. Theoretically probing the possible degradation mechanisms of an FeNC catalyst during the oxygen reduction reaction. Chem Sci. 2021; 12 (37): 12476- 12484.

[113]

Li J, Sougrati MT, Zitolo A, et al. Identification of durable and non-durable FeN_x sites in Fe-N-C materials for proton exchange membrane fuel cells. Nat Catal. 2021; 4 (1): 10- 19.

[114]

Miao Z, Wang X, Zhao Z, et al. Improving the stability of non-noble-metal M-N-C catalysts for proton-exchange-membrane fuel cells through M-N bond length and coordination regulation. Adv Mater. 2021; 33 (39): 2006613.

[115]

Xie X, He C, Li B, 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.

[116]

Jiménez-Morales I, Reyes-Carmona A, Dupont M, et al. Correlation between the surface characteristics of carbon supports and their electrochemical stability and performance in fuel cell cathodes. Carbon Energy. 2021; 3 (4): 654- 665.

[117]

Castanheira L, Silva WO, Lima FHB, Crisci A, Dubau L, Maillard F. Carbon corrosion in proton-exchange membrane fuel cells: effect of the carbon structure, the degradation protocol, and the Gas Atmosphere. ACS Catal. 2015; 5 (4): 2184- 2194.

[118]

Goellner V, Baldizzone C, Schuppert A, Sougrati MT, Mayrhofer K, Jaouen F. Degradation of Fe/N/C catalysts upon high polarization in acid medium. Phys Chem Chem Phys. 2014; 16 (34): 18454- 18462.

[119]

Schulenburg H, Stankov S, Schünemann V, et al. Catalysts for the oxygen reduction from heat-treated iron(III) tetramethoxyphenylporphyrin chloride: structure and stability of active sites. J Phys Chem B. 2003; 107 (34): 9034- 9041.

[120]

Kumar K, Gairola P, Lions M, et al. Physical and chemical considerations for improving catalytic activity and stability of non-precious metal oxygen reduction reaction catalysts. ACS Catal. 2018; 8 (12): 11264- 11276.

[121]

Kumar K, Dubau L, Mermoux M, et al. On the influence of oxygen on the degradation of Fe-N-C catalysts. Angew Chem Int Ed. 2020; 59 (8): 3235- 3243.

[122]

Choi CH, Choi WS, Kasian O, et al. Unraveling the nature of sites active toward hydrogen peroxide reduction in Fe-N-C catalysts. Angew Chem. 2017; 129 (30): 8935- 8938.

[123]

Wu Y, Muthukrishnan A, Nagata S, Nabae Y. Kinetic analysis of electrochemical oxygen reduction over a Fe/N/C catalyst considering the chemical decomposition of H₂O. J Phys Chem C. 2020; 124 (32): 17599- 17606.

[124]

Guo HL, Wang XF, Qian QY, Wang FB, Xia XH. A green approach to the synthesis of graphene nanosheets. ACS Nano. 2009; 3 (9): 2653- 2659.

[125]

Choi CH, Lim HK, Chung MW, et al. The Achilles' heel of iron-based catalysts during oxygen reduction in an acidic medium. Energy Environ Sci. 2018; 11 (11): 3176- 3182.

[126]

Yang N, Peng L, Li L, Li J, Wei Z. Theoretical research on the oxidation mechanism of doped carbon based catalysts for oxygen reduction reaction. Phys Chem Chem Phys. 2019; 21 (47): 26102- 26110.

[127]

Liu J, Wan X, Liu S, et al. Hydrogen passivation of M-N-C (M = Fe, Co) catalysts for storage stability and ORR activity improvements. Adv Mater. 2021; 33 (38): 2103600.

[128]

Tang C, Chen L, Li H, et al. Tailoring acidic oxygen reduction selectivity on single-atom catalysts via modification of first and second coordination spheres. J Am Chem Soc. 2021; 143 (20): 7819- 7827.

[129]

He Y, Guo H, Hwang S, et al. Single cobalt sites dispersed in hierarchically porous nanofiber networks for durable and high-power PGM-free cathodes in fuel cells. Adv Mater. 2020; 32 (46): 2003577.

[130]

Guo X, Lin S, Gu J, Zhang S, Chen Z, Huang S. Simultaneously achieving high activity and selectivity toward two-electron O₂ electroreduction: the power of single-atom catalysts. ACS Catal. 2019; 9 (12): 11042- 11054.

[131]

Zhao X, Liu Y. Origin of selective production of hydrogen peroxide by electrochemical oxygen reduction. J Am Chem Soc. 2021; 143 (25): 9423- 9428.

[132]

Cheng X, Yang J, Yan W, 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.

[133]

Hunter MA, Fischer JMTA, Yuan Q, Hankel M, Searles DJ. Evaluating the catalytic efficiency of paired, single-atom catalysts for the oxygen reduction reaction. ACS Catal. 2019; 9 (9): 7660- 7667.

[134]

Liu Y, Zhou G, Zhang Z, et al. Significantly improved electrocatalytic oxygen reduction by an asymmetrical Pacman dinuclear cobalt(II) porphyrin-porphyrin dyad. Chem Sci. 2020; 11 (1): 87- 96.

[135]

Zeng X, Shui J, Liu X, et al. Single-atom to single-atom grafting of Pt₁ onto Fe-N₄ center: Pt₁@Fe-N-C multifunctional electrocatalyst with significantly enhanced properties. Adv Energy Mater. 2018; 8 (1): 1701345.

[136]

Chong L, Wen J, Kubal J, et al. Ultralow-loading platinum-cobalt fuel cell catalysts derived from imidazolate frameworks. Science. 2018; 362 (6420): 1276- 1281.

[137]

Jeon T-Y, Yu S-H, Yoo SJ, Park H-Y, Kim S-K. Electrochemical determination of the degree of atomic surface roughness in Pt-Ni alloy nanocatalysts for oxygen reduction reaction. Carbon Energy. 2021; 3 (2): 375- 383.

[138]

Li J, Chen M, Cullen DA, et al. Atomically dispersed manganese catalysts for oxygen reduction in proton-exchange membrane fuel cells. Nat Catal. 2018; 1 (12): 935- 945.

[139]

Xia D, Yang X, Xie L, et al. Direct growth of carbon nanotubes doped with single atomic Fe-N₄ active sites and neighboring graphitic nitrogen for efficient and stable oxygen reduction electrocatalysis. Adv Funct Mater. 2019; 29 (49): 1906174.

[140]

Kübler M, Wagner S, Jurzinsky T, et al. Impact of surface functionalization on the intrinsic properties of the resulting Fe-N-C catalysts for fuel cell applications. Energy Technol. 2020; 8 (9): 2070091.

[141]

Ma L, Li J, Zhang Z, et al. Atomically dispersed dual Fe centers on nitrogen-doped bamboolike carbon nanotubes for efficient oxygen reduction. Nano Res. 2022; 15 (3): 1966- 1972.

[142]

Shu C, Tan Q, Deng C, et al. Hierarchically mesoporous carbon spheres coated with a single atomic Fe-N-C layer for balancing activity and mass transfer in fuel cells. Carbon Energy. 2022; 4 (1): 1- 11.

[143]

Harzer GS, Orfanidi A, El-Sayed H, Madkikar P, Gasteiger HA. Tailoring catalyst morphology towards high performance for low Pt loaded PEMFC cathodes. J Electrochem Soc. 2018; 165 (10): F770- F779.

[144]

Yin X, Feng L, Yang W, et al. Interface engineering of plasmonic induced Fe/N/C-F catalyst with enhanced oxygen catalysis performance for fuel cells application. Nano Res. 2022; 15 (3): 2138- 2146.

[145]

Banham D, Kishimoto T, Zhou Y, et al. Critical advancements in achieving high power and stable nonprecious metal catalyst-based MEAs for real-world proton exchange membrane fuel cell applications. Sci Adv. 2018; 4 (3): eaar7180.

[146]

Kabir S, Medina S, Wang G, Bender G, Pylypenko S, Neyerlin KC. Improving the bulk gas transport of Fe-N-C platinum group metal-free nanofiber electrodes via electrospinning for fuel cell applications. Nano Energy. 2020; 73: 104791.

[147]

Khandavalli S, Iyer R, Park JH, et al. Effect of dispersion medium composition and ionomer concentration on the microstructure and rheology of Fe-N-C platinum group metal-free catalyst inks for polymer electrolyte membrane fuel cells. Langmuir. 2020; 36 (41): 12247- 12260.

[148]

Uddin A, Dunsmore L, Zhang H, Hu L, Wu G, Litster S. High power density platinum group metal-free cathodes for polymer electrolyte fuel cells. ACS Appl Mater Interfaces. 2020; 12 (2): 2216- 2224.

[149]

Damjanović AM, Koyutürk B, Li Y-S, et al. Loading impact of a PGM-free catalyst on the mass activity in proton exchange membrane fuel cells. J Electrochem Soc. 2021; 168 (11): 114518.

[150]

Sun R, Xia Z, Xu X, Deng R, Wang S, Sun G. Periodic evolution of the ionomer/catalyst interfacial structures towards proton conductance and oxygen transport in polymer electrolyte membrane fuel cells. Nano Energy. 2020; 75: 104919.

[151]

Martinez U, Komini Babu S, Holby EF, Zelenay P. Durability challenges and perspective in the development of PGM-free electrocatalysts for the oxygen reduction reaction. Curr Opin Electrochem. 2018; 9: 224- 232.

[152]

Qiao Z, Hwang S, Li X, et al. 3D porous graphitic nanocarbon for enhancing the performance and durability of Pt catalysts: a balance between graphitization and hierarchical porosity. Energy Environ Sci. 2019; 12 (9): 2830- 2841.