L. Tang, H. Peng, J. Kang, et al., “Zn-Based Batteries for Sustainable Energy Storage: Strategies and Mechanisms,” Chemical Society Reviews 53 (2024): 4877–4925.

B. Ramasubramanian, J. Ling, R. Jose, and S. Ramakrishna, “Ten Major Challenges for Sustainable Lithium-Ion Batteries,” Cell Reports Physical Science 5 (2024): 102032.

Q. Wang, S. Kaushik, X. Xiao, and Q. Xu, “Sustainable Zinc–Air Battery Chemistry: Advances, Challenges and Prospects,” Chemical Society Reviews 52 (2023): 6139–6190.

J.-N. Liu, C.-X. Zhao, J. Wang, D. Ren, B.-Q. Li, and Q. Zhang, “A Brief History of Zinc–Air Batteries: 140 Years of Epic Adventures,” Energy & Environmental Science 15 (2022): 4542–4553.

X. Bi, Y. Jiang, R. Chen, et al., “Rechargeable Zinc–Air versus Lithium–Air Battery: From Fundamental Promises Toward Technological Potentials,” Advanced Energy Materials 14 (2024): 2302388.

D. Stock, S. Dongmo, J. Janek, and D. Schröder, “Benchmarking Anode Concepts: The Future of Electrically Rechargeable Zinc–Air Batteries,” ACS Energy Letters 4 (2019): 1287–1300.

K.-P. Kairies, Battery Storage Technology Improvements and Cost Reductions to 2030: A Deep Dive, 2017, https://policycommons.net/artifacts/12748560/battery-storage-technology-improvements-and-cost-reductions-to-2030/13646233/.

R. Dufo-López and J. L. Bernal-Agustín, “Techno-Economic Analysis of Grid-Connected Battery Storage,” Energy Conversion and Management 91 (2015): 394–404.

X. Yang, H. Wen, Y. Lin, et al., “Emerging Research Needs for Characterizing the Risks of Global Lithium Pollution Under Carbon Neutrality Strategies,” Environmental Science & Technology 57 (2023): 5103–5106.

W. Huang, X. Feng, X. Han, W. Zhang, and F. Jiang, “Questions and Answers Relating to Lithium-Ion Battery Safety Issues,” Cell Reports Physical Science 2 (2021): 100285.

F. Santos, A. Urbina, J. Abad, R. López, C. Toledo, and A. J. Fernández Romero, “Environmental and Economical Assessment for a Sustainable Zn/Air Battery,” Chemosphere 250 (2020): 126273.

J. Fu, Z. P. Cano, M. G. Park, A. Yu, M. Fowler, and Z. Chen, Advanced Materials 29 (2017): 1604685.

J. Zhang, Q. Zhou, Y. Tang, L. Zhang, and Y. Li, “Zinc–Air Batteries: Are They Ready for Prime Time,” Chemical Science 10 (2019): 8924–8929.

J. S. Lee, S. Tai Kim, R. Cao, et al., “Metal–Air Batteries With High Energy Density: Li–Air Versus Zn–Air,” Advanced Energy Materials 1 (2011): 34–50.

T. B. Reddy and D. Linden, Linden's Handbook of Batteries, 4th ed. (McGraw-Hill, 2011).

L. Peiseler, V. Schenker, K. Schatzmann, S. Pfister, V. Wood, and T. Schmidt, “Carbon Footprint Distributions of Lithium-Ion Batteries and Their Materials,” Nature Communications 15 (2024): 10301.

M. Romare and L. Dahllöf, “The Life Cycle Energy Consumption and Greenhouse Gas Emissions From Lithium-Ion Batteries,” IVL Svenska Miljöinstitutet (2017), https://www.diva-portal.org/smash/record.jsf?pid=diva2%3A1549706&dswid=-3136.

E. Emilsson and L. Dahllöf, Lithium-Ion Vehicle Battery Production-Status 2019 on Energy Use, CO₂ Emissions, Use of Metals, Products Environmental Footprint, and Recycling, IVL Svenska Miljöinstitutet, 2019.

K. Turcheniuk, D. Bondarev, V. Singhal, and G. Yushin, “Ten Years Left to Redesign Lithium-Ion Batteries,” Nature Publishing Group (London, UK) 559 (2018): 467–470.

S. Mir, S. Vij, and N. Dhawan, “Evaluation of End-of-Life Zinc–Air Hearing Aid Batteries for Zinc Recovery,” Minerals Engineering 198 (2023): 108082.

P. Xing, B. Ma, C. Wang, L. Wang, and Y. Chen, “A Simple and Effective Process for Recycling Zinc-Rich Paint Residue,” Waste Management 76 (2018): 234–241.

S. Maryam Sadeghi, J. Jesus, and H. M. V. M. Soares, “A Critical Updated Review of the Hydrometallurgical Routes for Recycling Zinc and Manganese From Spent Zinc-Based Batteries,” Waste Management 113 (2020): 342–350.

X. Hu, A. Robles, T. Vikström, P. Väänänen, M. Zackrisson, and G. Ye, “A Novel Process on the Recovery of Zinc and Manganese From Spent Alkaline and Zinc–Carbon Batteries,” Journal of Hazardous Materials 411 (2021): 124928.

D. Yadav and R. Banerjee, “Thermodynamic and Economic Analysis of the Solar Carbothermal and Hydrometallurgy Routes for Zinc Production,” Energy 247 (2022): 123242.

G. Lemaire, Method for Recovering Potassium Hydroxide and Zinc Oxide From Potassium Zincate Solutions, Google Patents, 1977.

S. S. Shinde, N. K. Wagh, C. H. Lee, et al., “Scaling-Up Insights for Zinc–Air Battery Technologies Realizing Reversible Zinc Anodes,” Advanced Materials 35 (2023): 2303509.

A. Baasner, F. Reuter, M. Seidel, et al., “The Role of Balancing Nanostructured Silicon Anodes and NMC Cathodes in Lithium-Ion Full-Cells With High Volumetric Energy Density,” Journal of the Electrochemical Society 167 (2020): 020516.

F. Wang, B. Wang, J. Li, et al., “Prelithiation: A Crucial Strategy for Boosting the Practical Application of Next-Generation Lithium Ion Battery,” ACS Nano 15 (2021): 2197–2218.

X. Chen, Z. Zhou, H. E. Karahan, Q. Shao, L. Wei, and Y. Chen, “Recent Advances in Materials and Design of Electrochemically Rechargeable Zinc–Air Batteries,” Small 14 (2018): 1801929.

F. Mahlendorf, A. Heinzel, C. Mueller, and D. Fuchs, “ Chapter 6 - Secondary Zinc-Air Batteries – Mechanically Rechargeable,” in Electrochemical Power Sources: Fundamentals, Systems, and Applications, eds. H. Arai, J. Garche, and L. Colmenares (Elsevier, 2021), 99–123.

C. Zhou, X. Chen, S. Liu, et al., “Superdurable Bifunctional Oxygen Electrocatalyst for High-Performance Zinc–Air Batteries,” Journal of the American Chemical Society 144 (2022): 2694–2704.

M. A. I. Mohd Shumiri, A. S. Mohd Najib, and N. A. Fadil, “Current Status and Advances in Zinc Anodes for Rechargeable Aqueous Zinc-Air Batteries,” Science and Technology of Advanced Materials 26 (2025): 2448418.

J. Yu, B. Q. Li, C. X. Zhao, J. N. Liu, and Q. Zhang, “Asymmetric Air Cathode Design for Enhanced Interfacial Electrocatalytic Reactions In High-Performance Zinc–Air Batteries,” Advanced Materials 32 (2020): 1908488.

K. Wang, P. Pei, Z. Ma, et al., “Growth of Oxygen Bubbles During Recharge Process in Zinc–Air Battery,” Journal of Power Sources 296 (2015): 40–45.

Y. He, W. Shang, M. Ni, Y. Huang, H. Zhao, and P. Tan, “In-Situ Observation of the Gas Evolution Process on the Air Electrode of Zn-Air Batteries During Charging,” Chemical Engineering Journal 427 (2022): 130862.

T.-H. Shen, L. Spillane, J. Peng, Y. Shao-Horn, and V. Tileli, “Switchable Wetting of Oxygen-Evolving Oxide Catalysts,” Nature Catalysis 5 (2022): 30–36.

G. Ren, M. Zhou, P. Hu, J.-F. Chen, and H. Wang, “Bubble-Water/Catalyst Triphase Interface Microenvironment Accelerates Photocatalytic OER via Optimizing Semi-Hydrophobic OH Radical,” Nature Communications 15 (2024): 2346.

N. Zhang, C. Deng, S. Tao, L. Guo, and Y. Cheng, “Bifunctional Oxygen Electrodes With Gradient Hydrophilic/Hydrophobic Reactive Interfaces for Metal Air Flow Batteries,” Chemical Engineering Science 224 (2020): 115795.

Y. He, Z. Zhao, Y. Cui, W. Shang, Y. Chen, and P. Tan, “Boosting Gaseous Oxygen Transport in a Zn-Air Battery for High-Rate Charging by a Bubble Diode-Inspired Air Electrode,” Energy Storage Materials 57 (2023): 360–370.

T. Han, H. Sun, J. Hu, et al., “Self-Assembly of Porous Curly Graphene Film as an Efficient Gas Diffusion Layer for High-Performance Zn-Air Batteries,” Carbon 223 (2024): 119025.

Y. He and P. Tan, “'Bubble-Diode' Breathable Electrodes for Fast Gas Transport,” Chemistry – A European Journal 30 (2024): e202303477.

C. Pei, Y. Peng, Y. Zhang, D. Tian, K. Liu, and L. Jiang, “An Integrated Janus Mesh: Underwater Bubble Antibuoyancy Unidirectional Penetration,” ACS Nano 12 (2018): 5489–5494.

B. Jańczuk and T. Białlopiotrowicz, “Surface Free-Energy Components of Liquids and Low Energy Solids and Contact Angles,” Journal of Colloid and Interface Science 127 (1989): 189–204.

M. P. Clark, M. Xiong, K. Cadien, and D. G. Ivey, “High Performance Oxygen Reduction/Evolution Electrodes for Zinc–Air Batteries Prepared by Atomic Layer Deposition of MnOx,” ACS Applied Energy Materials 3 (2019): 603–613.

W. Yan, C. Hsueh, C. Soong, F. Chen, C. Cheng, and S. Mei, “Effects of Fabrication Processes and Material Parameters of GDL on Cell Performance of PEM Fuel Cell,” International Journal of Hydrogen Energy 32 (2007): 4452–4458.

S. S. Shinde, J. Y. Jung, N. K. Wagh, et al., “Ampere-Hour-Scale Zinc–Air Pouch Cells,” Nature Energy 6 (2021): 592–604.

P. Moni, A. Deschamps, D. Schumacher, K. Rezwan, and M. Wilhelm, “A New Silicon Oxycarbide Based Gas Diffusion Layer for Zinc–Air Batteries,” Journal of Colloid and Interface Science 577 (2020): 494–502.

J. Liu, L. Jiang, Q. Tang, et al., “Amide-Functionalized Carbon Supports for Cobalt Oxide Toward Oxygen Reduction Reaction In Zn-Air Battery,” Applied Catalysis B Environment 148 (2014): 212–220.

W.-W. Tian, J.-T. Ren, X.-W. Lv, and Z.-Y. Yuan, “A ‘Gas-Breathing’ Integrated Air Diffusion Electrode Design With Improved Oxygen Utilization Efficiency for High-Performance Zn–Air Batteries,” Chemical Engineering Journal 431 (2022): 133210.

R. Khezri, S. R. Motlagh, M. Etesami, et al., “Balancing Current Density and Electrolyte Flow for Improved Zinc-Air Battery Cyclability,” Applied Energy 376 (2024): 124239.

X. Zheng, N. Mohammadi, A. Moreno Zuria, and M. Mohamedi, “Advanced Zinc–Air Batteries With Free-Standing Hierarchical Nanostructures of the Air Cathode for Portable Applications,” ACS Applied Materials & Interfaces 13 (2021): 61374–61385.

A. Jayakumar, S. Singamneni, M. Ramos, A. Al-Jumaily, and S. Pethaiah, “Manufacturing the Gas Diffusion Layer for PEM Fuel Cell Using a Novel 3D Printing Technique and Critical Assessment of the Challenges Encountered,” Materials 10 (2017): 796.

Y. Wang, R. Yi, G. Li, Q. Yi, and W. Fan, “Impact of Diffusion Layer Structure of Air Electrodes on Their Performance in Neutral Zinc/Iron - Air Batteries,” Journal of Alloys and Compounds 1010 (2025): 177492.

Z.-L. Wang, D. Xu, J.-J. Xu, and X.-B. Zhang, “Oxygen Electrocatalysts in Metal–Air Batteries: From Aqueous to Nonaqueous Electrolytes,” Chemical Society Reviews 43 (2014): 7746–7786.

T. C. Nagaiah, D. Gupta, S. D. Adhikary, A. Kafle, and D. Mandal, “Tuning Polyoxometalate Composites With Carbonaceous Materials Towards Oxygen Bifunctional Activity,” Journal of Materials Chemistry A 9 (2021): 9228–9237.

P. Trivedi, N. C. Minj, S. Mittal, B. Kamaraj, S. Yadav, and A. Sengeni, “How Common is it to Get an OER Overpotential That is <250 mV?,” Journal of Materials Chemistry A (2025), https://doi.org/10.1039/D5TA00009B.

Y. Pan, X. Xu, Y. Zhong, et al., “Direct Evidence of Boosted Oxygen Evolution Over Perovskite by Enhanced Lattice Oxygen Participation,” Nature Communications 11 (2020): 2002.

J. Huang, J. Zhang, and M. Eikerling, “Unifying Theoretical Framework for Deciphering the Oxygen Reduction Reaction on Platinum,” Physical Chemistry Chemical Physics 20 (2018): 11776–11786.

M. Gao, C. Li, R. Wang, S. Xiao, Z. Guo, and Y. Wang, “Noble Metal Catalysts for Metal-Air Batteries: From Nano-Level to Atom-Level,” Next Materials 2 (2024): 100126.

X. Zhong, X. Xiao, Q. Li, et al., “Understanding the Active site in Chameleon-Like Bifunctional Catalyst for Practical Rechargeable Zinc-Air Batteries,” Nature Communications 15 (2024): 9616.

Y. Li, J. Xu, F. Lan, et al., “Atomic-Level Tin Regulation for High-Performance Zinc–Air Batteries,” Journal of the American Chemical Society 147 (2025): 4833–4843.

S. Liu, T. Zeng, Z. He, et al., “Synergistic Effect of Ru Single Atoms and MnO₂ to Boost Oxygen Reduction/Evolution Activity via Strong Electronic Interaction,” Chemical Engineering Journal 499 (2024): 156051.

M. Zhang, H. Li, J. Chen, et al., “A low-Cost, Durable Bifunctional Electrocatalyst Containing Atomic Co and Pt Species for Flow Alkali-Al/Acid Hybrid Fuel Cell and Zn–Air Battery,” Advanced Functional Materials 33 (2023): 2303189.

G. Wang, J. Chang, S. Koul, A. Kushima, and Y. Yang, “CO₂ Bubble-Assisted Pt Exposure in PtFeNi Porous Film for High-Performance Zinc–Air Battery,” Journal of the American Chemical Society 143 (2021): 11595–11601.

S. Qiao, H. Shou, W. Xu, et al., “Regulating and Identifying the Structures of PdAu Alloys With Splendid Oxygen Reduction Activity for Rechargeable Zinc–Air Batteries,” Energy & Environmental Science 16 (2023): 5842–5851.

X. Luo, M. Yang, W. Song, et al., “Neutral Zn-Air Battery Assembled With Single-Atom Iridium Catalysts for Sensitive Self-Powered Sensing System,” Advanced Functional Materials 31 (2021): 2101193.

D. Zhao, Y. Zhu, Q. Wu, et al., “Low-Loading Ir Decorated Cobalt Encapsulated N-Doped Carbon Nanotubes/Porous Carbon Sheet Implements Efficient Hydrogen/Oxygen Trifunctional Electrocatalysis,” Chemical Engineering Journal 430 (2022): 132825.

N. Wang, S. Ning, X. Yu, et al., “Graphene Composites With Ru-RuO₂ Heterostructures: Highly Efficient Mott–Schottky-Type Electrocatalysts for pH-Universal Water Splitting and Flexible Zinc–Air Batteries,” Applied Catalysis, B: Environmental 302 (2022): 120838.

P. Varathan, P. Moni, S. Kumar Das, and A. K. Sahu, “High Performance Air Breathing Zinc–Air Battery With Pt−Ni and Pt−Co Bifunctional Electrocatalyst on N Activated Mesoporous Carbon,” Journal of the Electrochemical Society 170 (2023): 050536.

R. Majee, T. Das, S. Chakraborty, and S. Bhattacharyya, “Shaping a Doped Perovskite Oxide With Measured Grain Boundary Defects to Catalyze Bifunctional Oxygen Activation for a Rechargeable Zn–Air Battery,” ACS Applied Materials & Interfaces 12 (2020): 40355–40363.

M. M. Kumar, C. Aparna, A. K. Nayak, U. V. Waghmare, D. Pradhan, and C. R. Raj, “Surface Tailoring-Modulated Bifunctional Oxygen Electrocatalysis With CoP for Rechargeable Zn–Air Battery and Water Splitting,” ACS Applied Materials & Interfaces 16 (2024): 3542–3551.

F. Zhang, R. Ji, X. Zhu, et al., “Strain-Regulated Pt–NiO@ Ni Sub-Micron Particles Achieving Bifunctional Electrocatalysis for Zinc–Air Battery,” Small 19 (2023): 2301640.

J. Tian, Y. Song, X. Hao, et al.,“Greatly Enhanced Oxygen Reduction Reaction in Anion Exchange Membrane Fuel Cell and Zn-Air Battery via Hole Inner Edge Reconstruction of 2D Pd Nanomesh,” Advanced Materials 37 (2025): 2412051.

J. Zhang, W. Xu, Y. Liu, et al., “In Situ Precise Tuning of Bimetallic Electronic Effect for Boosting Oxygen Reduction Catalysis,” Nano Letters 21 (2021): 7753–7760.

Y. Li, J. Xu, F. Lan, et al.,“Breaking the Stability-Activity Trade-off of Oxygen Electrocatalyst by Gallium Bilateral-Regulation for High-Performance Zinc-Air Batteries,” Angewandte Chemie International Edition 64 (2025): e202420481.

Z. Qiu, X. Guo, S. Cao, et al., “High-Entropy Ag− Ru-Based Electrocatalysts With Dual-Active-Center for Highly Stable Ultra-Low-Temperature Zinc-Air Batteries,” Angewandte Chemie International Edition 64 (2025): e202415216.

W. Xu, E. Diesen, T. He, K. Reuter, and J. T. Margraf, “Discovering High Entropy Alloy Electrocatalysts in Vast Composition Spaces With Multiobjective Optimization,” Journal of the American Chemical Society 146 (2024): 7698–7707.

A. Li, Y. Tan, Y. Wang, et al.,“A General Sol-Gel Route to Fabricate Large-Area Highly-Ordered Metal Oxide Arrays Toward High-Performance Zinc-Air Batteries,” Small 21 (2025): 2409620.

N. Thakur, M. Kumar, D. Mandal, and T. C. Nagaiah, “Nickel Iron Phosphide/Phosphate as an Oxygen Bifunctional Electrocatalyst for High-Power-Density Rechargeable Zn–Air Batteries,” ACS Applied Materials & Interfaces 13 (2021): 52487–52497.

W. Zhang, J. Zhang, N. Wang, et al., “Two-Electron Redox Chemistry via Single-Atom Catalyst for Reversible Zinc–Air Batteries,” Nature Sustainability 7 (2024): 463–473.

S. W. Nam, T. H. Nguyen, D. T. Tran, et al., “Molecularly Engineered Potential of d-Orbital Modulated Iron-Bridged Delaminated MBene for Rechargeable Zn–Air Batteries,” Energy & Environmental Science 17 (2024): 6559–6570.

B. R. Wygant, K. Kawashima, and C. B. Mullins, “Catalyst or Precatalyst? The Effect of Oxidation on Transition Metal Carbide, Pnictide, and Chalcogenide Oxygen Evolution Catalysts,” ACS Energy Letters 3 (2018): 2956–2966.

C. Wei, Z. Feng, G. G. Scherer, J. Barber, Y. Shao-Horn, and Z. J. Xu,“Cations in Octahedral Sites: A Descriptor for Oxygen Electrocatalysis on Transition-Metal Spinels,” Advanced Materials 29 (2017): 1606800.

S. Lu, J. Jiang, H. Yang, et al., “Phase Engineering of Iron–Cobalt Sulfides for Zn–Air and Na–Ion Batteries,” ACS Nano 14 (2020): 10438–10451.

D. Gupta, A. Kafle, P. P. Mohanty, et al., “Self-Powered NH₃ Synthesis by Trifunctional Co2B-based High Power Density Zn–Air Batteries,” Journal of Materials Chemistry A 11 (2023): 12223–12235.

K. Tang, H. Hu, Y. Xiong, et al.,“Hydrophobization Engineering of the Air–Cathode Catalyst for Improved Oxygen Diffusion Towards Efficient Zinc–Air Batteries,” Angewandte Chemie 134 (2022): e202202671.

L. Wei, H. E. Karahan, S. Zhai, et al.,“Amorphous Bimetallic Oxide–Graphene Hybrids as Bifunctional Oxygen Electrocatalysts for Rechargeable Zn–Air Batteries,” Advanced Materials 29 (2017): 1701410.

Y. Jiang, Y.-P. Deng, R. Liang, et al., “d-Orbital Steered Active Sites Through Ligand Editing on Heterometal Imidazole Frameworks for Rechargeable Zinc–Air Battery,” Nature Communications 11 (2020): 5858.

Y. Li, A. Huang, L. Zhou, et al., “Main-Group Element-Boosted Oxygen Electrocatalysis of Cu-N-C Sites for Zinc–Air Battery With Cycling over 5000 h,” Nature Communications 15 (2024): 8365.

Y. Liu, H. Liu, L. Li, Y. Tang, Y. Sun, and J. Zhou,“Construction of Asymmetric Fe-N3P1 Sites on Freestanding Nitrogen/Phosphorus Co-Doped Carbon Nanofibers for Boosting Oxygen Electrocatalysis and Zinc–Air Batteries,” Small 21 (2025): 2501495.

A. Saad, Y. Gao, A. Ramiere, et al.,“Understanding the Surface Reconstruction on Ternary WxCoBx for Water Oxidation and Zinc–Air Battery Applications,” Small 18 (2022): 2201067.

Z. Li, X. Zhong, L. Gao, et al., “Asymmetric Coordination of Bimetallic Fe–Co Single-Atom Pairs Toward Enhanced Bifunctional Activity for Rechargeable Zinc–Air Batteries,” ACS Nano 18 (2024): 13006–13018.

J. Zhu, J. Chi, T. Cui, et al., “F Doping and P Vacancy Engineered FeCoP Nanosheets for Efficient and Stable Seawater Electrolysis at Large Current Density,” Applied Catalysis, B: Environmental 328 (2023): 122487.

A. Parra-Puerto, K. L. Ng, K. Fahy, A. E. Goode, M. P. Ryan, and A. Kucernak, “Supported Transition Metal Phosphides: Activity Survey for HER, ORR, OER, and Corrosion Resistance in Acid and Alkaline Electrolytes,” ACS Catalysis 9 (2019): 11515–11529.

N. Khodayar, A. Noori, M. S. Rahmanifar, et al., “An Ultra-High Mass-Loading Transition Metal Phosphide Electrocatalyst for Efficient Water Splitting and Ultra-Durable Zinc–Air Batteries,” Energy & Environmental Science 17 (2024): 5200–5215.

S. Li, Z. Geng, X. Wang, et al., “Optimizing the Surface State of Cobalt-Iron Bimetallic Phosphide via Regulating Phosphorus Vacancies,” Chemical Communications 56 (2020): 2602–2605.

S. Ghora, R. Chakraborty, S. Bag, M. M. Kumar, and C. Retna Raj, “Transition Metal Phosphide-Based Oxygen Electrocatalysts for Aqueous Zinc–Air Batteries,” Chemical Communications 61 (2025): 2636–2657.

C. Yao, J. Li, Z. Zhang, et al.,“Hierarchical Core–Shell Co₂N/CoP Embedded in N, P-Doped Carbon Nanotubes as Efficient Oxygen Reduction Reaction Catalysts for Zn-Air Batteries,” Small 18 (2022): 2108094.

Z. Li, Y. Zeng, D. Xiong, et al., “Interfacial Engineering of Cobalt Phosphide Heterostructures Confined in N,P-Doped Carbon for Efficient Bifunctional Electrocatalysis in Zn–Air Batteries,” Inorganic Chemistry Frontiers 11 (2024): 549–561.

S. Ren, L. Liu, F. Meng, et al., “Heteroatom-Doped Carbon Attached to Ultra-Fine Fe-NiCoP as High-Performance Oxygen Electrocatalyst for Zn-Air Batteries,” Energy Storage Materials 65 (2024): 103086.

Y. Feng, R. Wang, P. Dong, et al., “Enhanced Electrocatalytic Activity of Nickel Cobalt Phosphide Nanoparticles Anchored on Porous N-Doped Fullerene Nanorod for Efficient Overall Water Splitting,” ACS Applied Materials & Interfaces 13 (2021): 48949–48961.

Z. Wu, L. Huang, H. Liu, M. Li, and H. Wang, “Surface Oxidation of Transition Metal Sulfide and Phosphide Nanomaterials,” Nano Research 14 (2021): 2264–2267.

S.-H. Li, M.-Y. Qi, Z.-R. Tang, and Y.-J. Xu, “Nanostructured Metal Phosphides: From Controllable Synthesis to Sustainable Catalysis,” Chemical Society Reviews 50 (2021): 7539–7586.

H. Park, A. Encinas, J. P. Scheifers, Y. Zhang, and B. P. T. Fokwa, “Boron-Dependency of Molybdenum Boride Electrocatalysts for the Hydrogen Evolution Reaction,” Angewandte Chemie International Edition 56 (2017): 5575–5578.

S. Carenco, D. Portehault, C. Boissière, N. Mézailles, and C. Sanchez, “Nanoscaled Metal Borides and Phosphides: Recent Developments and Perspectives,” Chemical Reviews 113 (2013): 7981–8065.

P. Rao, D. Wu, T.-J. Wang, et al., “Single Atomic Cobalt Electrocatalyst for Efficient Oxygen Reduction Reaction,” EScience 2 (2022): 399–404.

M. A. Alemu, A. A. Assegie, M. Ilbas, R. Al Afif, and M. Z. Getie, “Biomass-Derived Metal-Free Nanostructured Carbon Electrocatalysts for High-Performance Rechargeable Zinc–Air Batteries,” Advanced Energy and Sustainability Research 6 (2025): 2400414.

S. Patra, R. Choudhary, E. Roy, R. Madhuri, and P. K. Sharma, “Heteroatom-Doped Graphene ‘Idli’: A Green and Foody Approach Towards Development of Metal Free Bifunctional Catalyst for Rechargeable Zinc–Air Battery,” Nano Energy 30 (2016): 118–129.

W. Chen, X. Pi, Z. Qu, et al.,“Pyridinic NB Pair-Doped Carbon Microspheres With Refined Hierarchical Architectures for Rechargeable Zinc-Air Batteries,” Applied Energy 377 (2025): 124511.

Y. Cheng, Y. Wang, Q. Wang, et al., “Hierarchically Porous Metal-Free Carbon With Record High Mass Activity for Oxygen Reduction and Zn-Air Batteries,” Journal of Materials Chemistry A 7 (2019): 9831–9836.

M. Cui, Y. Yuan, Y. Wu, et al.,“Graphdiyne-Induced CoN/CoS₂ Heterojunction: Boosting Efficiency for Bifunctional Oxygen Electrochemistry in Zinc-Air Batteries,” Chemsuschem 17 (2024): e202400832.

P. Cui, T. Li, X. Chi, et al., “Bamboo Derived N-Doped Carbon as a Bifunctional Electrode for High-Performance Zinc–Air Batteries,” Sustainable Energy & Fuels 7 (2023): 2717–2726.

C. Tang and Q. Zhang,“Nanocarbon for Oxygen Reduction Electrocatalysis: Dopants, Edges, and Defects,” Advanced Materials 29 (2017): 1604103.

Z. Fang, W. Kou, Y. Sui, et al., “Novel Air-Rechargeable Aqueous Zn-Based Batteries With N-Doped Hierarchical-Porous Carbon as the Capacitor-Type Cathode,” Energy Storage Materials 74 (2025): 103968.

J. Fang, X. Zhang, X. Wang, et al., “A Metal and Nitrogen Doped Carbon Composite With Both Oxygen Reduction and Evolution Active Sites for Rechargeable Zinc–Air Batteries,” Journal of Materials Chemistry A 8 (2020): 15752–15759.

P. Yu, L. Wang, F. Sun, et al.,“Co Nanoislands Rooted on Co–N–C Nanosheets as Efficient Oxygen Electrocatalyst for Zn–Air Batteries,” Advanced Materials 31 (2019): 1901666.

Y. He, S. Hwang, D. A. Cullen, et al., “Highly Active Atomically Dispersed CoN₄ Fuel Cell Cathode Catalysts Derived From Surfactant-Assisted MOFs: Carbon-Shell Confinement Strategy,” Energy & Environmental Science 12 (2019): 250–260.

K. Gao, M. Shen, C. Duan, et al., “Co-N-Doped Directional Multichannel PAN/CA-Based Electrospun Carbon Nanofibers as High-Efficiency Bifunctional Oxygen Electrocatalysts for Zn–Air Batteries,” ACS Sustainable Chemistry & Engineering 9 (2021): 17068–17077.

W. Xiao, M. Cheng, Y. Liu, et al., “Functional Metal/Carbon Composites Derived From Metal–Organic Frameworks: Insight Into Structures, Properties, Performances, and Mechanisms,” ACS Catalysis 13 (2023): 1759–1790.

C. Mi, H. Yu, L. Han, et al.,“Symmetric Electronic Structures of Active Sites to Boost Bifunctional Oxygen Electrocatalysis by MN4+4 Sites Directly From Initial Covalent Organic Polymers,” Advanced Functional Materials 33 (2023): 2303235.

Y. Sun, L. Wang, H. Li, et al., “N-, S-Codoped Porous Carbon With Trace Single-Atom Fe for Enhanced Oxygen Reduction With Robust Poison Resistance and Efficient Rechargeable Zinc–Air Battery,” Carbon Neutralization 4 (2025): e196.

L. Zhu, D. Zheng, Z. Wang, et al.,“A Confinement Strategy for Stabilizing ZIF-Derived Bifunctional Catalysts as a Benchmark Cathode of Flexible All-Solid-State Zinc–Air Batteries,” Advanced Materials 30 (2018): 1805268.

Y. Li, C. Zhong, J. Liu, et al.,“Atomically Thin Mesoporous Co3O4 Layers Strongly Coupled With N-rGO Nanosheets as High-Performance Bifunctional Catalysts for 1D Knittable Zinc–Air Batteries,” Advanced Materials 30 (2018): 1703657.

J. Su, Y. Wan, L. Feng, et al.,“'One-Stone, Two-Birds': Zinc-Rich Metal–Organic Frameworks as Precursors for High-Entropy Zn-Air Battery Electrocatalysts With Hierarchical Pore Structures,” Angewandte Chemie 137 (2025): e202413826.

W. Deng, Z. Song, M. Jing, T. Wu, W. Li, and G. Zou, “Highly Active Air Electrode Catalysts for Zn-Air Batteries: Catalytic Mechanism and Active Center From Obfuscation to Clearness,” Carbon Neutralization 3 (2024): 501–532.

K. Cui, Q. Wang, Z. Bian, G. Wang, and Y. Xu,“Supramolecular Modulation of Molecular Conformation of Metal Porphyrins Toward Remarkably Enhanced Multipurpose Electrocatalysis and Ultrahigh-Performance Zinc–Air Batteries,” Advanced Energy Materials 11 (2021): 2102062.

L. Wan, K. Zhao, Y.-C. Wang, et al., “Molecular Degradation of Iron Phthalocyanine During the Oxygen Reduction Reaction in Acidic Media,” ACS Catalysis 12 (2022): 11097–11107.

J. Jian, Z. Wang, Y. Qiao, et al., “NiCoP@CoNi-LDH/SSM as a Multifunctional Catalyst for High-Efficiency Water Splitting and Ultra-Long-Life Rechargeable Zinc–Air Batteries,” Green Chemistry 26 (2024): 6713–6722.

W. Sun, M. Ma, M. Zhu, et al., “Chemical Buffer Layer Enabled Highly Reversible Zn Anode for Deeply Discharging and Long-Life Zn–Air Battery,” Small 18 (2022): 2106604.

M. Shimizu, K. Hirahara, and S. Arai, “Morphology Control of Zinc Electrodeposition by Surfactant Addition for Alkaline-Based Rechargeable Batteries,” Physical Chemistry Chemical Physics 21 (2019): 7045–7052.

R. Chireau, “Power Sources 5; Research and Development in Non-Mechanical Electrical Power Sources”, Proceedings of the Ninth International Symposium, Brighton, Sussex, England (1975): 371–390.

J. R. Goldstein and B. Koretz, “Tests of a Full-Sized Mechanically Rechargeable Zinc–Air Battery in an Electric Vehicle,” IEEE Aerospace and Electronic Systems Magazine 8 (1993): 34–38.

K. Wang and J. Yu,“Lifetime Simulation of Rechargeable Zinc-Air Battery Based on Electrode Aging,” Journal of Energy Storage 28 (2020): 101191.

T. Wang, M. Kunimoto, T. Mori, et al.,“Carbonate Formation on Carbon Electrode in Rechargeable Zinc-Air Battery Revealed by In-Situ Raman Measurements,” Journal of Power Sources 533 (2022): 231237.

J.-F. Drillet, F. Holzer, T. Kallis, S. Müller, and V. M. Schmidt, “Influence of CO₂ on the Stability of Bifunctional Oxygen Electrodes for Rechargeable Zinc/Air Batteries and Study of Different CO₂ Filter Materials,” Physical Chemistry Chemical Physics 3 (2001): 368–371.

B. Amunátegui, A. Ibáñez, M. Sierra, and M. Pérez, “Electrochemical Energy Storage for Renewable Energy Integration: Zinc–Air Flow Batteries,” Journal of Applied Electrochemistry 48 (2018): 627–637.

Z. Zhao, X. Fan, J. Ding, W. Hu, C. Zhong, and J. Lu, “Challenges in Zinc Electrodes for Alkaline Zinc–Air Batteries: Obstacles to Commercialization,” ACS Energy Letters 4 (2019): 2259–2270.

W. Xie and F. Wan, “Immobilization of Polyoxometalate-Based Sulfonated Ionic Liquids on UiO-66-2COOH Metal-Organic Frameworks for Biodiesel Production via One-Pot Transesterification-Esterification of Acidic Vegetable Oils,” Chemical Engineering Journal 365 (2019): 40–50.

L. Kong, J. Qiao, Q. Ruan, et al.,“A Very Low Charge Potential for Zinc-Air Battery Promoted by Photochemical Effect of Triazine-Based Conjugated Polymer Nanolayer Coated TiO₂,” Journal of Power Sources 536 (2022): 231507.

Z. Zhou, Y. Zhang, P. Chen, et al., “Graphene Oxide-Modified Zinc Anode for Rechargeable Aqueous Batteries,” Chemical Engineering Science 194 (2019): 142–147.

F. Wang, O. Borodin, T. Gao, et al., “Highly Reversible Zinc Metal Anode for Aqueous Batteries,” Nature Materials 17 (2018): 543–549.

Q. Xu, W. Zhou, T. Xin, Z. Zheng, X. Yuan, and J. Liu, “Practical Zn Anodes Enabled by a Ti-MOF-Derived Coating for Aqueous Batteries,” Journal of Materials Chemistry A 10 (2022): 12247–12257.

X. Chen, W. Li, S. Hu, et al.,“Polyvinyl Alcohol Coating Induced Preferred Crystallographic Orientation in Aqueous Zinc Battery Anodes,” Nano Energy 98 (2022): 107269.

M. Deyab and G. Mele,“Polyaniline/Zn-Phthalocyanines Nanocomposite For Protecting Zinc Electrode in Zn-Air Battery,” Journal of Power Sources 443 (2019): 227264.

D. Stock, S. Dongmo, F. Walther, J. Sann, J. R. Janek, and D. Schröder, “Homogeneous Coating With an Anion-Exchange Ionomer Improves the Cycling Stability of Secondary Batteries With Zinc Anodes,” ACS Applied Materials & Interfaces 10 (2018): 8640–8648.

R. Khezri, S. R. Motlagh, M. Etesami, A. A. Mohamad, and S. Kheawhom, “ Anode Corrosion and Mitigation in Metal–Air Batteries—II (Zn–Air),” in Corrosion and Degradation in Fuel Cells, Supercapacitors and Batteries, ed. V. S. Saji (Springer, Cham 2024), 425–442.

L. Lei, Y. Sun, X. Wang, Y. Jiang, and J. Li, “Strategies to Enhance Corrosion Resistance of Zn Electrodes for Next Generation Batteries,” Frontiers in Materials 7 (2020): 96.

M. Lee, I. Choi, A. Kim, et al., “Supramolecular Metal–Organic Framework for the High Stability of Aqueous Rechargeable Zinc Batteries,” ACS Nano 18 (2024): 22586–22595.

N. Kadam and A. Sarkar,“A System for Recharging Zn-Air Battery With High Reversibility Using a Water-in-Salt Electrolyte,” Journal of Energy Storage 54 (2022): 105265.

L. Hong, X. Wu, Y. S. Liu, et al.,“Self-Adapting and Self-Healing Hydrogel Interface With Fast Zn²⁺ Transport Kinetics for Highly Reversible Zn Anodes,” Advanced Functional Materials 33 (2023): 2300952.

M. C. Huang, S. H. Huang, S. C. Chiu, et al., “Improved Electrochemical Performance of Zn–Air Secondary Batteries via Novel Organic Additives,” Journal of the Chinese Chemical Society 65 (2018): 1239–1244.

L. Chladil, O. Čech, J. Smejkal, and P. Vanýsek, “Study of Zinc Deposited in the Presence of Organic Additives for Zinc-Based Secondary Batteries,” Journal of Energy Storage 21 (2019): 295–300.

T. Nagy, L. Nagy, Z. Erdélyi, et al., “Environmentally Friendly Zn-Air Rechargeable Battery With Heavy Metal Free Charcoal Based Air Cathode,” Electrochimica Acta 368 (2021): 137592.

A. R. Mainar, L. C. Colmenares, H.-J. Grande, and J. A. Blázquez, “Enhancing the Cycle Life of a Zinc–Air Battery by Means of Electrolyte Additives and Zinc Surface Protection,” Batteries 4 (2018): 46.

Z. Hou, X. Zhang, X. Li, Y. Zhu, J. Liang, and Y. Qian, “Surfactant Widens the Electrochemical Window of an Aqueous Electrolyte for Better Rechargeable Aqueous Sodium/Zinc Battery,” Journal of Materials Chemistry A 5 (2017): 730–738.

S. Hosseini, W. Lao-Atiman, S. J. Han, A. Arpornwichanop, T. Yonezawa, and S. Kheawhom, “Discharge Performance of Zinc–Air Flow Batteries Under the Effects of Sodium Dodecyl Sulfate and Pluronic F-127,” Scientific Reports 8 (2018): 14909.

M.-Y. Wang, R.-B. Huang, J.-F. Xiong, J.-H. Tian, J.-F. Li, and Z.-Q. Tian,“Critical Role and Recent Development of Separator In Zinc-Air Batteries,” Acta Physico-Chim Sinica 40 (2024): 2307017.

A. Abbasi, Y. Xu, R. Khezri, et al.,“Advances in Characteristics Improvement of Polymeric Membranes/Separators for Zinc-Air Batteries,” Materials Today Sustainability 18 (2022): 100126.

G. M. Wu, S. J. Lin, J. H. You, and C. C. Yang, “Study of High-Anionic Conducting Sulfonated Microporous Membranes for Zinc–Air Electrochemical Cells,” Materials Chemistry and Physics 112 (2008): 798–804.

H.-J. Lee, J.-M. Lim, H.-W. Kim, et al., “Electrospun Polyetherimide Nanofiber Mat-Reinforced, Permselective Polyvinyl Alcohol Composite Separator Membranes: A Membrane-Driven Step Closer Toward Rechargeable Zinc–Air Batteries,” Journal of Membrane Science 499 (2016): 526–537.

N. Suppanucroa, W. Yoopensuk, J. Pimoei, et al.,“Enhanced Long-Term Stability of Zinc-Air Batteries Using a Quaternized PVA-Chitosan Composite Separator With Thin-Layered MoS₂,” Electrochimica Acta 510 (2025): 145361.

M. T. Tsehaye, N. H. Choi, P. Fischer, et al., “Anion Exchange Membranes Incorporating Multi N-Spirocyclic Quaternary Ammonium Cations via Ultraviolet-Initiated Polymerization for Zinc Slurry-Air Flow Batteries,” ACS Applied Energy Materials 5 (2022): 7069–7080.

Z. Zhao, B. Liu, X. Fan, et al.,“An Easily Assembled Boltless Zinc–Air Battery Configuration for Power Systems,” Journal of Power Sources 458 (2020): 228061.

X.-H. Liu, X. Liu, and H.-J. Peng, “Zinc–Air Flow Batteries at the Nexus of Materials Innovation and Reaction Engineering,” Industrial & Engineering Chemistry Research 62 (2023): 20963–20978.

J. Goldstein, I. Brown, and B. Koretz, “New Developments in the Electric Fuel Ltd. Zinc/Air System,” Journal of Power Sources 80 (1999): 171–179.

Z. Zhao, B. Liu, X. Fan, et al.,“Methods for Producing an Easily Assembled Zinc-Air Battery,” MethodsX 7 (2020): 100973.

S. S. Swain, A. K. Swain, and B. K. Jena, “Anion Exchange Polymer Membrane (AEPM)-Based Separators: An Unexplored Frontier for ZAB and AAB Systems,” Journal of Materials Chemistry A 13 (2025): 6274–6313.

Z. Yang, P. Li, J. Li, et al.,“All-in-One Polymer Gel Electrolyte Towards High-Efficiency and Stable Fiber Zinc-Air Battery,” Angewandte Chemie 137 (2025): e202414772.

M. Wu, N. Huang, M. Lv, et al., “Organic-Inorganic Hybrid Hydrogel Electrolyte for High-Performance Quasi-Solid-State Zinc–Air Batteries,” Frontiers of Chemical Science and Engineering 19 (2025): 15.

J. A. Vega, C. Chartier, and W. E. Mustain, “Effect of Hydroxide and Carbonate Alkaline Media on Anion Exchange Membranes,” Journal of Power Sources 195 (2010): 7176–7180.

K. W. Kim, H. Kim, J. Choi, S.-J. Choi, and K. R. Yoon, “Internally Connected Porous PVA/PAA Membrane With Cross-Aligned Nanofiber Network for Facile and Long-Lasting Ion Transport in Zinc–Air Batteries,” Energy Storage Materials 71 (2024): 103594.

D. Zhao, Y. Zhu, W. Cheng, W. Chen, Y. Wu, and H. Yu,“Cellulose-Based Flexible Functional Materials for Emerging Intelligent Electronics,” Advanced Materials 33 (2021): 2000619.

A. Kongara, A. K. Samuel, G. Kapadia, and A. K. Chandiran, “Mechanically Rechargeable Zinc–Air Batteries for Two- and Three-Wheeler Electric Vehicles in Emerging Markets,” Communications Materials 5 (2024): 244.

J. Goldstein, B. Koretz, and Y. Harats, Field Test of the Electric Fuel {trademark} Zinc-Air Refuelable Battery System for Electric Vehicles (Institute of Electrical and Electronics Engineers, 1996), https://www.osti.gov/biblio/474426https://www.osti.gov/biblio/474426.

K. Tweed, EOS Energy Storage Closes $23M Funding Round for Cheap Grid Batteries, 2016.

E. Wesoff, Fluidic Energy is the Biggest Zinc-Air Battery Startup You Haven't Heard of (gtm, 2015).

T. Zhang, N. Wu, Y. Zhao, et al.,“Frontiers and Structural Engineering for Building Flexible Zinc–Air Batteries,” Advancement of Science 9 (2022): 2103954.

K. Kordesch, V. Hacker, W. Vielstich, A. Lamm, and H. A. Gasteiger, Handbook of Fuel Cells–Fundamentals, Technology and Applications (2003), 765–773, https://www.osti.gov/etdeweb/biblio/20480552.

W. Lao-Atiman, K. Bumroongsil, A. Arpornwichanop, P. Bumroongsakulsawat, S. Olaru, and S. Kheawhom, “Model-Based Analysis of an Integrated Zinc–Air Flow Battery/Zinc Electrolyzer System,” Frontiers in Energy Research 7 (2019): 15.

H. Jafarizadeh, E. Yamini, S. M. Zolfaghari, F. Esmaeilion, M. E. H. Assad, and M. Soltani, “Navigating Challenges in Large-Scale Renewable Energy Storage: Barriers, Solutions, and Innovations,” Energy Reports 12 (2024): 2179–2192.

X. Fu, F. He, X. Liu, et al.,“Direct Solar Energy Conversion on Zinc–Air Battery,” Proceedings of the National Academy of Sciences 121 (2024): e2318777121.

X. Xu, F. Song, and X. Hu, “A Nickel Iron Diselenide-Derived Efficient Oxygen-Evolution Catalyst,” Nature Communications 7 (2016): 12324.

L. Ran, J. Hou, S. Cao, et al.,“Defect Engineering of Photocatalysts for Solar Energy Conversion,” Solar RRL 4 (2020): 1900487.

Z. Wang, R. Liu, J. Wang, B. Wang, M. Zhu, and S. Hu, “High Energy Conversion Efficiency and Cycle Durability of Solar-Powered Self-Sustaining Light-Assisted Rechargeable Zinc–Air Batteries System,” Energy Storage Materials 74 (2025): 103897.

S. Zheng, M. Chen, K. Chen, et al., “Solar-Light-Responsive Zinc–Air Battery With Self-Regulated Charge–Discharge Performance Based on Photothermal Effect,” ACS Applied Materials & Interfaces 15 (2023): 2985–2995.

G. G. Yadav, X. Wei, and M. Meeus, “ Chapter 3 - Primary Zinc-air Batteries,” in Electrochemical Power Sources: Fundamentals, Systems, and Applications eds. H. Arai, J. Garche, and L. Colmenares (Elsevier, 2021), 23–45.

B. Koretz and J. R. Goldstein, IECEC-97 Proceedings of the Thirty-Second Intersociety Energy Conversion Engineering Conference (Cat. No. 97CH6203) (IEEE, 1997), 2, 877–882.