REFERENCES

1. Asadi M, Sayahpour B, Abbasi P, et al. A lithium-oxygen battery with a long cycle life in an air-like atmosphere. Nature 2018;555:502-6.

2. Gourdin G, Xiao N, McCulloch W, Wu Y. Use of polarization curves and impedance analyses to optimize the “triple-phase boundary” in K-O₂ batteries. ACS Appl Mater Interfaces 2019;11:2925-34.

3. Liu Y, Zhan F, Wang B, et al. Three-dimensional composite catalysts for Al-O₂ batteries composed of CoMn₂O₄ Nanoneedles supported on nitrogen-doped carbon nanotubes/graphene. ACS Appl Mater Interfaces 2019;11:21526-35.

4. Vardar G, Nelson EG, Smith JG, et al. Identifying the discharge product and reaction pathway for a secondary Mg/O₂ battery. Chem Mater 2015;27:7564-8.

5. Li B, Zhang S, Wang B, Xia Z, Tang C, Zhang Q. A porphyrin covalent organic framework cathode for flexible Zn-air batteries. Energy Environ Sci 2018;11:1723-9.

6. Qin L, Schkeryantz L, Zheng J, Xiao N, Wu Y. Superoxide-based K-O₂ batteries: highly reversible oxygen redox solves challenges in air electrodes. J Am Chem Soc 2020;142:11629-40.

7. Xia C, Black R, Fernandes R, Adams B, Nazar LF. The critical role of phase-transfer catalysis in aprotic sodium oxygen batteries. Nat Chem 2015;7:496-501.

8. Ryu WH, Gittleson FS, Thomsen JM, et al. Heme biomolecule as redox mediator and oxygen shuttle for efficient charging of lithium-oxygen batteries. Nat Commun 2016;7:12925.

9. Bruce PG, Freunberger SA, Hardwick LJ, Tarascon JM. Li-O₂ and Li-S batteries with high energy storage. Nat Mater 2011;11:19-29.

10. Thotiyl MM, Freunberger SA, Peng Z, Chen Y, Liu Z, Bruce PG. A stable cathode for the aprotic Li-O₂ battery. Nat Mater 2013;12:1050-6.

11. Meng F, Zhong H, Bao D, Yan J, Zhang X. In situ coupling of strung Co₄N and intertwined N-C fibers toward free-standing bifunctional cathode for robust, efficient, and flexible Zn-Air batteries. J Am Chem Soc 2016;138:10226-31.

12. Cai X, Lai L, Lin J, Shen Z. Recent advances in air electrodes for Zn-air batteries: electrocatalysis and structural design. Mater Horiz 2017;4:945-76.

13. Xu N, Qiao J. Recent progress in bifunctional catalysts for zinc-air batteries. J Electrochem 2020;26:531-562.

14. Lu Z. Computational discovery of energy materials in the era of big data and machine learning: a critical review. Materials Reports: Energy 2021;1:100047.

15. Li C, Guo Z, Yang B, Liu Y, Wang Y, Xia Y. A rechargeable Li-CO₂ battery with a gel polymer electrolyte. Angew Chem Int Ed Engl 2017;56:9126-30.

16. Qiao Y, Yi J, Wu S, et al. Li-CO₂ Electrochemistry: a new strategy for CO₂ fixation and energy storage. Joule 2017;1:359-70.

17. Wang T, Sang X, Zheng W, et al. Gas diffusion strategy for inserting atomic iron sites into graphitized carbon supports for unusually high-efficient CO₂ electroreduction and high-performance Zn-CO₂ batteries. Adv Mater 2020;32:e2002430.

18. Wang K, Wu Y, Cao X, Gu L, Hu J. A Zn-CO₂ flow battery generating electricity and methane. Adv Funct Mater 2019;30:1908965.

19. Liu B, Sun Y, Liu L, Xu S, Yan X. Advances in manganese-based oxides cathodic electrocatalysts for Li-air batteries. Adv Funct Mater 2018;28:1704973.

20. Wang R, Chen Z, Hu N, Xu C, Shen Z, Liu J. Nanocarbon-based electrocatalysts for rechargeable aqueous Li/Zn-Air batteries. ChemElectroChem 2018;5:1745-63.

21. Ma Z, Yuan X, Li L, et al. A review of cathode materials and structures for rechargeable lithium-air batteries. Energy Environ Sci 2015;8:2144-98.

22. Wang Y, Lu Y. Nonaqueous lithium-oxygen batteries: reaction mechanism and critical open questions. Energy Storage Materials 2020;28:235-46.

23. Ma L, Yu T, Tzoganakis E, et al. Fundamental understanding and material challenges in rechargeable nonaqueous Li-O₂ batteries: recent progress and perspective. Adv Energy Mater 2018;8:1800348.

24. Balaish M, Jung J, Kim I, Ein-eli Y. A critical review on functionalization of air-cathodes for nonaqueous Li-O₂ batteries. Adv Funct Mater 2020;30:1808303.

25. Black R, Adams B, Nazar LF. Non-aqueous and hybrid Li-O₂ batteries. Adv Energy Mater 2012;2:801-15.

26. Wang G, Tu F, Xie J, et al. High-performance Li-O₂ batteries with controlled Li₂O₂ growth in graphene/Au-nanoparticles/Au-nanosheets sandwich. Adv Sci (Weinh) 2016;3:1500339.

27. Zhao C, Yu C, Banis MN, et al. Decoupling atomic-layer-deposition ultrafine RuO₂ for high-efficiency and ultralong-life Li-O₂ batteries. Nano Energy 2017;34:399-407.

28. Song S, Xu W, Zheng J, et al. Complete Decomposition of Li₂CO₃ in Li-O₂ batteries using Ir/B₄C as noncarbon-based oxygen electrode. Nano Lett 2017;17:1417-24.

29. Zhang P, Zhang S, He M, et al. Realizing the embedded growth of large Li₂O₂ aggregations by matching different metal oxides for high-capacity and high-rate lithium oxygen batteries. Adv Sci (Weinh) 2017;4:1700172.

30. Zhao W, Li X, Yin R, et al. Urchin-like NiO-NiCo₂O₄ heterostructure microsphere catalysts for enhanced rechargeable non-aqueous Li-O₂ batteries. Nanoscale 2018;11:50-9.

31. Liang R, Hu A, Li M, Ran Z, Shu C, Long J. Defect regulation of heterogeneous nickel-based oxides via interfacial engineering for long-life lithium-oxygen batteries. Electrochimica Acta 2019;321:134716.

32. Xu N, Zhang Y, Wang M, et al. High-performing rechargeable/flexible zinc-air batteries by coordinated hierarchical Bi-metallic electrocatalyst and heterostructure anion exchange membrane. Nano Energy 2019;65:104021.

33. Xia Q, Zhao L, Zhang Z, et al. MnCo₂S₄-CoS_1.097 Heterostructure nanotubes as high efficiency cathode catalysts for stable and long-life lithium-oxygen batteries under high current conditions. Adv Sci (Weinh) 2021;8:e2103302.

34. Xia Q, Zhao L, Li D, et al. Phase modulation of 1T/2HMoSe₂ nanoflowers for highly efficient bifunctional electrocatalysis in rechargeable Li-O₂ batteries. J Mater Chem A 2021;9:19922-31.

35. Hu A, Lv W, Lei T, et al. Heterostructured NiS₂/ZnIn₂S₄ realizing toroid-like Li₂O₂ deposition in lithium-oxygen batteries with low-donor-number solvents. ACS Nano 2020;14:3490-9.

36. Dong S, Chen X, Zhang K, et al. Molybdenum nitride based hybrid cathode for rechargeable lithium-O₂ batteries. Chem Commun (Camb) 2011;47:11291-3.

37. Idrees M, Batool S, Kong J, et al. Polyborosilazane derived ceramics - nitrogen sulfur dual doped graphene nanocomposite anode for enhanced lithium ion batteries. Electrochimica Acta 2019;296:925-37.

38. Lee G, Sung M, Kim J, Song HJ, Kim D. Synergistic effect of CuGeO₃/graphene composites for efficient oxygen-electrode electrocatalysts in Li-O₂ batteries. Adv Energy Mater 2018;8:1801930.

39. Tan G, Chong L, Amine R, et al. Toward highly efficient electrocatalyst for Li-O₂ batteries using biphasic N-doping cobalt@graphene multiple-capsule heterostructures. Nano Lett 2017;17:2959-66.

40. Xu JJ, Wang ZL, Xu D, Zhang LL, Zhang XB. Tailoring deposition and morphology of discharge products towards high-rate and long-life lithium-oxygen batteries. Nat Commun 2013;4:2438.

41. Mou S, Wu T, Xie J, et al. Boron phosphide nanoparticles: a nonmetal catalyst for high-selectivity electrochemical reduction of CO₂ to CH₃OH. Adv Mater 2019;31:e1903499.

42. Beck A, Huang X, Artiglia L, et al. The dynamics of overlayer formation on catalyst nanoparticles and strong metal-support interaction. Nat Commun 2020;11:3220.

43. Kwon O, Sengodan S, Kim K, et al. Exsolution trends and co-segregation aspects of self-grown catalyst nanoparticles in perovskites. Nat Commun 2017;8:15967.

44. Higaki T, Li Y, Zhao S, et al. Atomically tailored gold nanoclusters for catalytic application. Angew Chem Int Ed Engl 2019;58:8291-302.

45. Rong W, Zou H, Zang W, et al. Size-dependent activity and selectivity of atomic-level copper nanoclusters during CO/CO₂ electroreduction. Angew Chem Int Ed Engl 2021;60:466-72.

46. Zhao J, Jin R. Heterogeneous catalysis by gold and gold-based bimetal nanoclusters. Nano Today 2018;18:86-102.

47. Qiao B, Wang A, Yang X, et al. Single-atom catalysis of CO oxidation using Pt1/FeOx. Nat Chem 2011;3:634-41.

48. Peng Y, Lu B, Chen S. Carbon-supported single atom catalysts for electrochemical energy conversion and storage. Adv Mater 2018;30:e1801995.

49. Li S, Hao X, Abudula A, Guan G. Nanostructured Co-based bifunctional electrocatalysts for energy conversion and storage: current status and perspectives. J Mater Chem A 2019;7:18674-707.

50. Sun T, Xu L, Wang D, Li Y. Metal organic frameworks derived single atom catalysts for electrocatalytic energy conversion. Nano Res 2019;12:2067-80.

51. Zhu C, Shi Q, Xu BZ, et al. Hierarchically porous M-N-C (M = Co and Fe) single-atom electrocatalysts with robust MN_x active moieties enable enhanced ORR performance. Adv Energy Mater 2018;8:1801956.

52. Wang Y, Li Q, Zhang L, et al. A gel-limiting strategy for large-scale fabrication of Fe-N-C single-atom ORR catalysts. J Mater Chem A 2021;9:7137-42.

53. Liu F, Yan N, Zhu G, et al. Fe-N-C single-atom catalysts with an axial structure prepared by a new design and synthesis method for ORR. New J Chem 2021;45:13004-14.

54. Tavakkoli M, Flahaut E, Peljo P, et al. Mesoporous single-atom-doped grapheme-carbon nanotube hybrid: synthesis and tunable electrocatalytic activity for oxygen evolution and reduction reactions. ACS Catal 2020;10:4647-58.

55. Deng Q, Zhao J, Wu T, Chen G, Hansen HA, Vegge T. 2D transition metal-TCNQ sheets as bifunctional single-atom catalysts for oxygen reduction and evolution reaction (ORR/OER). J Catal 2019;370:378-84.

56. Ying Y, Fan K, Luo X, Qiao J, Huang H. Unravelling the origin of bifunctional OER/ORR activity for single-atom catalysts supported on C₂N by DFT and machine learning. J Mater Chem A 2021;9:16860-7.

57. Zhu C, Shi Q, Feng S, Du D, Lin Y. Single-atom catalysts for electrochemical water splitting. ACS Energy Lett 2018;3:1713-21.

58. Zeng L, Dai C, Liu B, Xue C. Oxygen-assisted stabilization of single-atom Au during photocatalytic hydrogen evolution. J Mater Chem A 2019;7:24217-21.

59. Zhang J, Xu X, Yang L, Cheng D, Cao D. Single-atom Ru doping induced phase transition of MoS₂ and S vacancy for hydrogen evolution reaction. Small Methods 2019;3:1900653.

60. Gao D, Liu T, Wang G, Bao X. Structure sensitivity in single-atom catalysis toward CO₂ electroreduction. ACS Energy Lett 2021;6:713-27.

61. Li M, Wang H, Luo W, Sherrell PC, Chen J, Yang J. Heterogeneous single-atom catalysts for electrochemical CO₂ reduction reaction. Adv Mater 2020;32:e2001848.

62. Cao S, Wei S, Wei X, et al. Can N, S cocoordination promote single atom catalyst performance in CO₂RR? Small 2021;17:e2100949.

63. Dopilka A, Zhao R, Weller JM, Bobev S, Peng X, Chan CK. Experimental and computational study of the lithiation of Ba₈Al_yGe_46-y based type I germanium clathrates. ACS Appl Mater Interfaces 2018;10:37981-93.

64. Lee YW, Kim DM, Kim SJ, et al. In situ synthesis and characterization of Ge embedded electrospun carbon nanostructures as high performance anode material for lithium-ion batteries. ACS Appl Mater Interfaces 2016;8:7022-9.

65. Ma W, Wang Y, Yang Y, et al. Temperature-dependent Li storage performance in nanoporous Cu-Ge-Al alloy. ACS Appl Mater Interfaces 2019;11:9073-82.

66. Yu J, Li B, Zhao C, Zhang Q. Seawater electrolyte-based metal-air batteries: from strategies to applications. Energy Environ Sci 2020;13:3253-68.

67. Sun Y, Liu X, Jiang Y, et al. Recent advances and challenges in divalent and multivalent metal electrodes for metal-air batteries. J Mater Chem A 2019;7:18183-208.

68. Liu Q, Chang Z, Li Z, Zhang X. Flexible metal-air batteries: progress, challenges, and perspectives. Small Methods 2018;2:1700231.

69. Watanabe M, Thomas ML, Zhang S, Ueno K, Yasuda T, Dokko K. Application of ionic liquids to energy storage and conversion materials and devices. Chem Rev 2017;117:7190-239.

70. Lyu Z, Zhou Y, Dai W, et al. Recent advances in understanding of the mechanism and control of Li₂O₂ formation in aprotic Li-O₂ batteries. Chem Soc Rev 2017;46:6046-72.

71. Li Y, Lu J. Metal-air batteries: will they be the future electrochemical energy storage device of choice? ACS Energy Lett 2017;2:1370-7.

72. Ma L, Chen S, Wang D, et al. Super-stretchable zinc-air batteries based on an alkaline-tolerant dual-network hydrogel electrolyte. Adv Energy Mater 2019;9:1803046.

73. Zhang Y, Wu Y, You W, et al. Deeply rechargeable and hydrogen-evolution-suppressing zinc anode in alkaline aqueous electrolyte. Nano Lett 2020;20:4700-7.

74. Zhong C, Liu B, Ding J, et al. Decoupling electrolytes towards stable and high-energy rechargeable aqueous zinc-manganese dioxide batteries. Nat Energy 2020;5:440-9.

75. Lu J, Li L, Park JB, Sun YK, Wu F, Amine K. Aprotic and aqueous Li-O₂ batteries. Chem Rev 2014;114:5611-40.

76. Pan J, Xu YY, Yang H, Dong Z, Liu H, Xia BY. Advanced architectures and relatives of air electrodes in zn-air batteries. Adv Sci (Weinh) 2018;5:1700691.

77. Lee J, Hwang B, Park M, Kim K. Improved reversibility of Zn anodes for rechargeable Zn-air batteries by using alkoxide and acetate ions. Electrochimica Acta 2016;199:164-71.

78. Zhang Y, Deng Y, Wang J, et al. Recent progress on flexible Zn-air batteries. Energy Storage Materials 2021;35:538-49.

79. Zhong Y, Xu X, Wang W, Shao Z. Recent advances in metal-organic framework derivatives as oxygen catalysts for zinc-air batteries. Batteries & Supercaps 2019;2:272-89.

80. Zhao Z, Fan X, Ding J, Hu W, Zhong C, Lu J. Challenges in zinc electrodes for alkaline zinc-air batteries: obstacles to commercialization. ACS Energy Lett 2019;4:2259-70.

81. Zelger C, Süßenbacher M, Laskos A, Gollas B. State of charge indicators for alkaline zinc-air redox flow batteries. Journal of Power Sources 2019;424:76-81.

82. Xie J, Wang Y. Recent development of CO₂ electrochemistry from Li-CO₂ batteries to Zn-CO₂ batteries. Acc Chem Res 2019;52:1721-9.

83. Chen Y, Mei Y, Li M, et al. Highly selective CO₂ conversion to methane or syngas tuned by CNTs@non-noble-metal cathodes in Zn-CO₂ flow batteries. Green Chem 2021;23:8138-46.

84. Gao S, Jin M, Sun J, et al. Coralloid Au enables high-performance Zn-CO₂ battery and self-driven CO production. J Mater Chem A 2021;9:21024-31.

85. Liu X, Tao S, Zhang J, Zhu Y, Ma R, Lu J. Ultrathin p-n type Cu₂O/CuCoCr-layered double hydroxide heterojunction nanosheets for photo-assisted aqueous Zn-CO₂ batteries. J Mater Chem A 2021;9:26061-8.

86. Xie J, Wang X, Lv J, et al. Reversible aqueous zinc-CO₂ batteries based on CO₂-HCOOH interconversion. Angew Chem Int Ed Engl 2018;57:16996-7001.

87. Kwak WJ, Rosy, Sharon D, et al. Lithium-oxygen batteries and related systems: potential, status, and future. Chem Rev 2020;120:6626-83.

88. Aurbach D, Mccloskey BD, Nazar LF, Bruce PG. Advances in understanding mechanisms underpinning lithium-air batteries. Nat Energy 2016:1.

89. Chang Z, Xu J, Liu Q, Li L, Zhang X. Recent progress on stability enhancement for cathode in rechargeable non-aqueous lithium-oxygen battery. Adv Energy Mater 2015;5:1500633.

90. Lyu Z, Yang L, Luan Y, et al. Effect of oxygen adsorbability on the control of Li₂O₂ growth in Li-O₂ batteries: implications for cathode catalyst design. Nano Energy 2017;36:68-75.

91. Li F, Chen J. Mechanistic evolution of aprotic lithium-oxygen batteries. Adv Energy Mater 2017;7:1602934.

92. Takechi K, Shiga T, Asaoka T. A Li-O₂/CO₂ battery. Chem Commun (Camb) 2011;47:3463-5.

93. Hu A, Shu C, Xu C, et al. Design strategies toward catalytic materials and cathode structures for emerging Li-CO₂ batteries. J Mater Chem A 2019;7:21605-33.

94. Mu X, Pan H, He P, Zhou H. Li-CO₂ and Na-CO₂ batteries: toward greener and sustainable electrical energy storage. Adv Mater 2020;32:e1903790.

95. Li X, Yang S, Feng N, He P, Zhou H. Progress in research on Li-CO₂ batteries: mechanism, catalyst and performance. Chinese J Catal 2016;37:1016-24.

96. Jiao Y, Qin J, Sari HMK, Li D, Li X, Sun X. Recent progress and prospects of Li-CO₂ batteries: mechanisms, catalysts and electrolytes. Energy Stor Mater 2021;34:148-70.

97. Mitchell S, Pérez-Ramírez J. Single atom catalysis: a decade of stunning progress and the promise for a bright future. Nat Commun 2020;11:4302.

98. Zhang L, Wang Y, Niu Z, Chen J. Single atoms on graphene for energy storage and conversion. Small Methods 2019;3:1800443.

99. Zhu C, Fu S, Shi Q, Du D, Lin Y. Single-atom electrocatalysts. Angew Chem Int Ed Engl 2017;56:13944-60.

100. Yang XF, Wang A, Qiao B, Li J, Liu J, Zhang T. Single-atom catalysts: a new frontier in heterogeneous catalysis. Acc Chem Res 2013;46:1740-8.

101. Ma L, Zhu G, Wang D, et al. Emerging metal single atoms in electrocatalysts and batteries. Adv Funct Mater 2020;30:2003870.

102. Zhang Z, Zhao X, Xi S, et al. Atomically dispersed cobalt trifunctional electrocatalysts with tailored coordination environment for flexible rechargeable Zn-air battery and self-driven water splitting. Adv Energy Mater 2020;10:2002896.

103. Sun H, Wang M, Zhang S, et al. Boosting oxygen dissociation over bimetal sites to facilitate oxygen reduction activity of zinc-air battery. Adv Funct Mater 2021;31:2006533.

104. Zhao L, Rong X, Niu Y, et al. Ostwald ripening tailoring hierarchically porous Na₃V₂(PO₄)₂O₂F hollow nanospheres for superior high-rate and ultrastable sodium ion storage. Small 2020;16:e2004925.

105. Li L, Chang X, Lin X, Zhao ZJ, Gong J. Theoretical insights into single-atom catalysts. Chem Soc Rev 2020;49:8156-78.

106. Zheng Y, Jiao Y, Zhu Y, et al. Molecule-level g-C₃N₄ coordinated transition metals as a new class of electrocatalysts for oxygen electrode reactions. J Am Chem Soc 2017;139:3336-9.

107. Huang D, Luo Y, Li S, et al. Recent advances in tuning the electronic structures of atomically dispersed M-N-C materials for efficient gas-involving electrocatalysis. Mater Horiz 2020;7:970-86.

108. Hossain MD, Liu Z, Zhuang M, et al. Rational design of grapheme-supported single atom catalysts for hydrogen evolution reaction. Adv Energy Mater 2019;9:1803689.

109. Wang X, Chen Z, Zhao X, et al. Regulation of coordination number over single Co sites: triggering the efficient electroreduction of CO₂. Angew Chem Int Ed Engl 2018;57:1944-8.

110. Pan F, Zhang H, Liu K, et al. Unveiling active sites of CO₂ reduction on nitrogen-coordinated and atomically dispersed iron and cobalt catalysts. ACS Catal 2018;8:3116-22.

111. Yuan K, Sfaelou S, Qiu M, et al. Synergetic contribution of boron and Fe-Nx species in porous carbons toward efficient electrocatalysts for oxygen reduction reaction. ACS Energy Lett 2018;3:252-60.

112. Ren W, Tan X, Yang W, et al. Isolated diatomic Ni-Fe metal-nitrogen sites for synergistic electroreduction of CO₂. Angew Chem Int Ed Engl 2019;58:6972-6.

113. Osmieri L, Escudero-cid R, Monteverde Videla AH, Ocón P, Specchia S. Performance of a Fe-N-C catalyst for the oxygen reduction reaction in direct methanol fuel cell: cathode formulation optimization and short-term durability. Applied Catalysis B: Environmental 2017;201:253-65.

114. Fei H, Dong J, Feng Y, et al. General synthesis and definitive structural identification of MN₄C₄ single-atom catalysts with tunable electrocatalytic activities. Nat Catal 2018;1:63-72.

115. Du C, Gao Y, Wang J, Chen W. A new strategy for engineering a hierarchical porous carbon-anchored Fe single-atom electrocatalyst and the insights into its bifunctional catalysis for flexible rechargeable Zn-air batteries. J Mater Chem A 2020;8:9981-90.

116. Chen G, Liu P, Liao Z, et al. Zinc-mediated template synthesis of Fe-N-C electrocatalysts with densely accessible Fe-N_x active sites for efficient oxygen reduction. Adv Mater 2020;32:e1907399.

117. Zeng Z, Yi L, He J, et al. Hierarchically porous carbon with pentagon defects as highly efficient catalyst for oxygen reduction and oxygen evolution reactions. J Mater Sci 2020;55:4780-91.

118. Ji D, Fan L, Li L, et al. Atomically transition metals on self-supported porous carbon flake arrays as binder-free air cathode for wearable zinc-air batteries. Adv Mater 2019;31:e1808267.

119. Han X, Ling X, Wang Y, 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 Engl 2019;58:5359-64.

120. Wu H, Li H, Zhao X, et al. Highly doped and exposed Cu(i)-N active sites within graphene towards efficient oxygen reduction for zinc-air batteries. Energy Environ Sci 2016;9:3736-45.

121. Yang Y, Wang C, Gao S, et al. Incorporation of Cu-N_x cofactors into graphene encapsulated Co as biomimetic electrocatalysts for efficient oxygen reduction. Nanoscale 2018;10:21076-86.

122. Sun H, Liu S, Wang M, Qian T, Xiong J, Yan C. Updating the intrinsic activity of a single-atom site with a P-O bond for a rechargeable Zn-air battery. ACS Appl Mater Interfaces 2019;11:33054-61.

123. Chen Y, Ji S, Zhao S, et al. Enhanced oxygen reduction with single-atomic-site iron catalysts for a zinc-air battery and hydrogen-air fuel cell. Nat Commun 2018;9:5422.

124. Yang Y, Mao K, Gao S, et al. O-, N-atoms-coordinated Mn cofactors within a graphene framework as bioinspired oxygen reduction reaction electrocatalysts. Adv Mater 2018;30:e1801732.

125. Han X, Ling X, Yu D, et al. Atomically dispersed binary Co-Ni sites in nitrogen-doped hollow carbon nanocubes for reversible oxygen reduction and evolution. Adv Mater 2019;31:e1905622.

126. Zhu X, Zhang D, Chen C, et al. Harnessing the interplay of Fe-Ni atom pairs embedded in nitrogen-doped carbon for bifunctional oxygen electrocatalysis. Nano Energy 2020;71:104597.

127. Gong S, Wang C, Jiang P, Hu L, Lei H, Chen Q. Designing highly efficient dual-metal single-atom electrocatalysts for the oxygen reduction reaction inspired by biological enzyme systems. J Mater Chem A 2018;6:13254-62.

128. Zheng W, Yang J, Chen H, et al. Atomically defined undercoordinated active sites for highly efficient CO₂ electroreduction. Adv Funct Mater 2019;30:1907658.

129. Yang R, Xie J, Liu Q, et al. A trifunctional Ni-N/P-O-codoped graphene electrocatalyst enables dual-model rechargeable Zn-CO₂/Zn-O₂ batteries. J Mater Chem A 2019;7:2575-80.

130. Wang P, Ren Y, Wang R, et al. Atomically dispersed cobalt catalyst anchored on nitrogen-doped carbon nanosheets for lithium-oxygen batteries. Nat Commun 2020;11:1576.

131. Shui JL, Karan NK, Balasubramanian M, Li SY, Liu DJ. Fe/N/C composite in Li-O₂ battery: studies of catalytic structure and activity toward oxygen evolution reaction. J Am Chem Soc 2012;134:16654-61.

132. Song LN, Zhang W, Wang Y, et al. Tuning lithium-peroxide formation and decomposition routes with single-atom catalysts for lithium-oxygen batteries. Nat Commun 2020;11:2191.

133. Hu X, Luo G, Zhao Q, et al. Ru single atoms on N-doped carbon by spatial confinement and ionic substitution strategies for high-performance Li-O₂ batteries. J Am Chem Soc 2020;142:16776-86.

134. Zhao W, Wang J, Yin R, et al. Single-atom Pt supported on holey ultrathin g-C₃N₄ nanosheets as efficient catalyst for Li-O₂ batteries. J Colloid Interface Sci 2020;564:28-36.

135. Hu C, Gong L, Xiao Y, et al. High-performance, long-life, rechargeable Li-CO₂ batteries based on a 3D holey graphene cathode implanted with single iron atoms. Adv Mater 2020;32:e1907436.

136. Zhang B, Jiao Y, Chao D, et al. Targeted synergy between adjacent Co atoms on graphene oxide as an efficient new electrocatalyst for Li-CO₂ batteries. Adv Funct Mater 2019;29:1904206.

137. Zang W, Sumboja A, Ma Y, et al. Single Co atoms anchored in porous N-doped carbon for efficient zinc-air battery cathodes. ACS Catal 2018;8:8961-9.

138. Yang ZK, Yuan C, Xu A. Confined pyrolysis within a nanochannel to form a highly efficient single iron site catalyst for Zn-air batteries. ACS Energy Lett 2018;3:2383-9.

139. Li BQ, Zhao CX, Chen S, et al. Framework-porphyrin-derived single-atom bifunctional oxygen electrocatalysts and their applications in Zn-air batteries. Adv Mater 2019;31:e1900592.

140. Qiu HJ, Du P, Hu K, et al. Metal and nonmetal codoped 3D nanoporous graphene for efficient bifunctional electrocatalysis and rechargeable Zn-air batteries. Adv Mater 2019;31:e1900843.

141. Tang C, Wang B, Wang HF, Zhang Q. Defect engineering toward atomic Co-N_x-C in hierarchical graphene for rechargeable flexible solid Zn-air batteries. Adv Mater 2017;29:1703185.

142. Wu J, Zhou H, Li Q, et al. Densely populated isolated single CoN site for efficient oxygen electrocatalysis. Adv Energy Mater 2019;9:1900149.

143. Pan Y, Liu S, Sun K, et al. A bimetallic Zn/Fe polyphthalocyanine-derived single-atom Fe-N₄ catalytic site:a superior trifunctional catalyst for overall water splitting and Zn-air batteries. Angew Chem Int Ed Engl 2018;57:8614-8.

144. Wagh NK, Shinde SS, Lee CH, et al. Densely colonized isolated Cu-N single sites for efficient bifunctional electrocatalysts and rechargeable advanced Zn-air batteries. Appl Catal B: Environ 2020;268:118746.

145. Zhao J, Qin R, Liu R. Urea-bridging synthesis of nitrogen-doped carbon tube supported single metallic atoms as bifunctional oxygen electrocatalyst for zinc-air battery. Applied Catalysis B: Environmental 2019;256:117778.

146. Zhang J, Liu Y, Yu Z, et al. Boosting the performance of the Fe-N-C catalyst for the oxygen reduction reaction by introducing single-walled carbon nanohorns as branches on carbon fibers. J Mater Chem A 2019;7:23182-90.

147. Yang L, Shi L, Wang D, Lv Y, Cao D. Single-atom cobalt electrocatalysts for foldable solid-state Zn-air battery. Nano Energy 2018;50:691-8.

148. Zhang X, Han X, Jiang Z, et al. Atomically dispersed hierarchically ordered porous Fe-N-C electrocatalyst for high performance electrocatalytic oxygen reduction in Zn-Air battery. Nano Energy 2020;71:104547.

149. Yang ZK, Yuan CZ, Xu AW. A rationally designed Fe-tetrapyridophenazine complex: a promising precursor to a single-atom Fe catalyst for an efficient oxygen reduction reaction in high-power Zn-air cells. Nanoscale 2018;10:16145-52.

150. Lyu X, Li G, Chen X, et al. Atomic cobalt on defective bimodal mesoporous carbon toward efficient oxygen reduction for zinc-air batteries. Small Methods 2019;3:1800450.

151. Wang J, Liu W, Luo G, et al. Synergistic effect of well-defined dual sites boosting the oxygen reduction reaction. Energy Environ Sci 2018;11:3375-9.

152. Zheng W, Chen F, Zeng Q, et al. A universal principle to accurately synthesize atomically dispersed metal-N₄ sites for CO₂ electroreduction. Nanomicro Lett 2020;12:108.

153. Hai X, Xi S, Mitchell S, et al. Scalable two-step annealing method for preparing ultra-high-density single-atom catalyst libraries. Nat Nanotechnol 2022;17:174-81.