Electrolysis of low-grade and saline surface water (2024)

References

  1. Vörösmarty, C. J. et al. Global threats to human water security and river biodiversity. Nature 467, 555–561 (2010).

    Google Scholar

  2. Spröte, W. in A Concise Encyclopedia of the United Nations Vol. 07404 (ed Volger, H.) 147–152 (Brill, 2010).

  3. The Future of Hydrogen (International Energy Agency, 2019).

  4. Bezdek, R. H. The hydrogen economy and jobs of the future. Renew. Energy Environ. Sustain. 4, 1 (2019).

    Google Scholar

  5. Moliner, R., Lázaro, M. J. & Suelves, I. Analysis of the strategies for bridging the gap towards the Hydrogen Economy. Int. J. Hydrog. Energy 41, 19500–19508 (2016).

    Google Scholar

  6. Deutsch, T. G. & Turner, J. A. Semiconductor Materials for Photoelectrolysis: 2014 Annual Progress Report U. S. DOE Hydrogen & Fuel Cells Program (Department of Energy, 2014).

  7. Ramsden, T., Ruth, M., Diakov, V., Laffen, M. & Timbario, T. A. Hydrogen Pathways: Updated Cost, Well-to-Wheels Energy Use, and Emissions for the Current Technology Status of Ten Hydrogen Production, Delivery, and Distribution Scenarios (National Renewable Energy Laboratory, 2013).

  8. Ursúa, A., Gandía, L. M. & Sanchis, P. Hydrogen production from water electrolysis: current status and future trends. Proc. IEEE 100, 410–426 (2012).

    Google Scholar

  9. Xiang, C., Papadantonakis, K. M. & Lewis, N. S. Principles and implementations of electrolysis systems for water splitting. Mater. Horiz. 3, 169–173 (2016).

    Google Scholar

  10. Matute, G., Yusta, J. M. & Correas, L. C. Techno-economic modelling of water electrolysers in the range of several MW to provide grid services while generating hydrogen for different applications: a case study in Spain applied to mobility with FCEVs. Int. J. Hydrog. Energy 44, 17431–17442 (2019).

    Google Scholar

  11. Chardonnet, C. et al. Study on Early Business Cases for H2 in Energy Storage and More Broadly Power To H2 Applications (EU Commission, 2017).

  12. Karagiannis, I. C. & Soldatos, P. G. Water desalination cost literature: review and assessment. Desalination 223, 448–456 (2008).

    Google Scholar

  13. Fourmond, V., Jacques, P. A., Fontecave, M. & Artero, V. H2 evolution and molecular electrocatalysts: Determination of Overpotentials and effect of hom*oconjugation. Inorg. Chem. 49, 10338–10347 (2010).

    Google Scholar

  14. Bennett, J. E. Electrodes for generation of hydrogen and oxygen from seawater. Int. J. Hydrog. Energy 5, 401–408 (1980).

    Google Scholar

  15. Katsounaros, I. et al. The effective surface pH during reactions at the solid-liquid interface. Electrochem. commun. 13, 634–637 (2011).

    Google Scholar

  16. Auinger, M. et al. Near-surface ion distribution and buffer effects during electrochemical reactions. Phys. Chem. Chem. Phys. 13, 16384–16394 (2011).

    Google Scholar

  17. Dionigi, F., Reier, T., Pawolek, Z., Gliech, M. & Strasser, P. Design criteria, operating conditions, and nickel-iron hydroxide catalyst materials for selective seawater electrolysis. ChemSusChem 9, 962–972 (2016). In this study, a general design criterion for oxygen-selective seawater splitting is derived from thermodynamic and kinetic considerations. Noble-metal-free NiFe double hydroxide electrocatalysts are demonstrated for selective oxygen evolution in seawater.

  18. Kapp, E. M. The precipitation of calcium and magnesium from sea water by sodium hydroxide. Biol. Bull. 55, 453–458 (1928).

    Google Scholar

  19. Kirk, D. W. & Ledas, A. E. Precipitate formation during sea water electrolysis. Int. J. Hydrog. Energy 7, 925–932 (1982).

    Google Scholar

  20. Dresp, S. & Strasser, P. Non-noble metal oxides and their application as bifunctional catalyst in reversible fuel cells and rechargeable air batteries. ChemCatChem 10, 4162–4171 (2018).

    Google Scholar

  21. Dresp, S. et al. Direct electrolytic splitting of seawater: activity, selectivity, degradation, and recovery studied from the molecular catalyst structure to the electrolyzer cell level. Adv. Energy Mater. 8, 1800338 (2018). This work reports a nanostructured NiFe-layered double hydroxide and Pt nanoparticles for electrolysis of artificial alkaline seawater. Membrane-induced stability losses are investigated and a recovery effect is identified using an on/off cycle.

    Google Scholar

  22. Adbel-Aal, H. K. & Hussein, I. A. Parametric study for saline water electrolysis: part 1-hydrogen production. Int. J. Hydrog. Energy 18, 485–489 (1993).

    Google Scholar

  23. Oh, B. S. et al. Formation of hazardous inorganic by-products during electrolysis of seawater as a disinfection process for desalination. Sci. Total Environ. 408, 5958–5965 (2010).

    Google Scholar

  24. Dresp, S., Dionigi, F., Klingenhof, M. & Strasser, P. Direct electrolytic splitting of seawater: opportunities and challenges. ACS Energy Lett. 4, 933–942 (2019).

    Google Scholar

  25. Carmo, M., Fritz, D. L., Mergel, J. & Stolten, D. A comprehensive review on PEM water electrolysis. Int. J. Hydrog. Energy 38, 4901–4934 (2013).

    Google Scholar

  26. Vincent, I. & Bessarabov, D. Low cost hydrogen production by anion exchange membrane electrolysis: A review. Renew. Sustain. Energy Rev. 81, 1690–1704 (2018).

    Google Scholar

  27. Meng, Y. et al. Review: recent progress in low-temperature proton-conducting ceramics. J. Mater. Sci. 54, 9291–9312 (2019).

    Google Scholar

  28. Laguna-Bercero, M. A. Recent advances in high temperature electrolysis using solid oxide fuel cells: a review. J. Power Sources 203, 4–16 (2012).

    Google Scholar

  29. Mauritz, K. A. & Moore, R. B. State of understanding of Nafion. Chem. Rev. 104, 4535–4586 (2004).

    Google Scholar

  30. Chae, K. J. et al. Mass transport through a proton exchange membrane (Nafion) in microbial fuel cells. Energy Fuels 22, 169–176 (2008).

    Google Scholar

  31. Müller, M. et al. Water management in membrane electrolysis and options for advanced plants. Int. J. Hydrog. Energy 44, 10147–10155 (2019).

    Google Scholar

  32. Schalenbach, M., Lueke, W. & Stolten, D. Hydrogen diffusivity and electrolyte permeability of the Zirfon PERL separator for alkaline water electrolysis. J. Electrochem. Soc. 163, 1480–1488 (2016).

    Google Scholar

  33. Lim, C. K., Liu, Q., Zhou, J., Sun, Q. & Chan, S. H. High-temperature electrolysis of synthetic seawater using solid oxide electrolyzer cells. J. Power Sources 342, 79–87 (2017).

    Google Scholar

  34. Hine, F., O’Brien, T. F. & Bommaraju, T. V. Handbook of Chlor-alkali Technology, Volume I: Fundamentals (Springer, 2005).

  35. Karlsson, R. K. B. & Cornell, A. Selectivity between oxygen and chlorine evolution in the chlor-alkali and chlorate processes. Chem. Rev. 116, 2982–3028 (2016).

    Google Scholar

  36. Kumari, S., Turner White, R., Kumar, B. & Spurgeon, J. M. Solar hydrogen production from seawater vapor electrolysis. Energy Environ. Sci. 9, 1725–1733 (2016).

    Google Scholar

  37. Heremans, G. et al. Vapor-fed solar hydrogen production exceeding 15% efficiency using earth abundant catalysts and anion exchange membrane. Sustain. Energy Fuels 1, 2061–2065 (2017).

    Google Scholar

  38. Kida, T. et al. Water vapor electrolysis with proton-conducting graphene oxide nanosheets. ACS Sustain. Chem. Eng. 6, 11753–11758 (2018).

    Google Scholar

  39. McCrory, C. C. L. et al. Benchmarking hydrogen evolving reaction and oxygen evolving reaction electrocatalysts for solar water splitting devices. J. Am. Chem. Soc. 137, 4347–4357 (2015).

    Google Scholar

  40. Gong, M. et al. An advanced Ni–Fe layered double hydroxide electrocatalyst for water oxidation. J. Am. Chem. Soc. 135, 8452–8455 (2013).

    Google Scholar

  41. Martindale, B. C. M. & Reisner, E. Bi-functional iron-only electrodes for efficient water splitting with enhanced stability through in situ electrochemical regeneration. Adv. Energy Mater. 6, 1502095 (2016). This report uses Fe-only materials as bi-functional electrocatalysts for both of the water splitting half reactions in alkaline media. The Fe materials show greater activity compared to previously reported bi-functional Co and Ni catalysts.

    Google Scholar

  42. Huang, W.-H. & Lin, C.-Y. Iron phosphate modified calcium iron oxide as an efficient and robust catalyst in electrocatalyzing oxygen evolution from seawater. Faraday Discuss. 215, 205–215 (2019).

    Google Scholar

  43. Juodkazytė, J. et al. Electrolytic splitting of saline water: durable nickel oxide anode for selective oxygen evolution. Int. J. Hydrog. Energy 44, 5929–5939 (2019). This study investigates a nickel oxide layer for electrocatalytic water oxidation and provides mechanistic insights into Ni(IV)-mediated electrocatalytic oxidation of water in alkaline chloride medium.

    Google Scholar

  44. Trasatti, S. Electrocatalysis in the anodic evolution of oxygen and chlorine. Electrochim. Acta 29, 1503–1512 (1984).

    Google Scholar

  45. Hansen, H. A. et al. Electrochemical chlorine evolution at rutile oxide (110) surfaces. Phys. Chem. Chem. Phys. 12, 283–290 (2010).

    Google Scholar

  46. Exner, K. S., Anton, J., Jacob, T. & Over, H. Controlling selectivity in the chlorine evolution reaction over RuO2-based catalysts. Angew. Chem. Int. Ed. 53, 11032–11035 (2014).

    Google Scholar

  47. Surendranath, Y. & Dinca, M. Electrolyte-dependent electrosynthesis and activity of cobalt-based water oxidation catalysts. J. Am. Chem. Soc. 131, 2615–2620 (2009).

    Google Scholar

  48. Cheng, F. et al. Synergistic action of Co-Fe layered double hydroxide electrocatalyst and multiple ions of sea salt for efficient seawater oxidation at near-neutral pH. Electrochim. Acta 251, 336–343 (2017).

    Google Scholar

  49. Zhao, Y. et al. Charge state manipulation of cobalt selenide catalyst for overall seawater electrolysis. Adv. Energy Mater. 8, 1801926 (2018).

    Google Scholar

  50. Zeradjanin, A. R., Menzel, N., Schuhmann, W. & Strasser, P. On the faradaic selectivity and the role of surface inhom*ogeneity during the chlorine evolution reaction on ternary Ti-Ru-Ir mixed metal oxide electrocatalysts. Phys. Chem. Chem. Phys. 16, 13741–13747 (2014).

    Google Scholar

  51. Macounová, K., Makarova, M., Jirkovský, J., Franc, J. & Krtil, P. Parallel oxygen and chlorine evolution on Ru1-xNixO2-y nanostructured electrodes. Electrochim. Acta 53, 6126–6134 (2008).

    Google Scholar

  52. Kishor, K., Saha, S., Parashtekar, A. & Pala, R. G. S. Increasing chlorine selectivity through weakening of oxygen adsorbates at surface in Cu doped RuO2 during seawater electrolysis. J. Electrochem. Soc. 165, J3276–J3280 (2018).

    Google Scholar

  53. Arikawa, T., Murakami, Y. & Takasu, Y. Simultaneous determination of chlorine and oxygen evolving at RuO2/Ti and RuO2-TiO2/Ti anodes by differential electrochemical mass spectroscopy. J. Appl. Electrochem. 28, 511–516 (1998).

    Google Scholar

  54. Karlsson, R. K. B., Hansen, H. A., Bligaard, T., Cornell, A. & Pettersson, L. G. M. Ti atoms in Ru0.3Ti0.7O2 mixed oxides form active and selective sites for electrochemical chlorine evolution. Electrochim. Acta 146, 733–740 (2014).

    Google Scholar

  55. Exner, K. S., Anton, J., Jacob, T. & Over, H. Chlorine evolution reaction on ruo2 (110): ab initio atomistic thermodynamics study - Pourbaix diagrams. Electrochim. Acta 120, 460–466 (2014).

    Google Scholar

  56. Sohrabnejad-Eskan, I. et al. Temperature-dependent kinetic studies of the chlorine evolution reaction over RuO2(110) model electrodes. ACS Catal. 7, 2403–2411 (2017).

    Google Scholar

  57. Petrykin, V., Macounova, K., Shlyakhtin, O. A. & Krtil, P. Tailoring the selectivity for electrocatalytic oxygen evolution on ruthenium oxides by zinc substitution. Angew. Chem. Int. Ed. 49, 4813–4815 (2010).

    Google Scholar

  58. Nong, H. N. et al. A unique oxygen ligand environment facilitates water oxidation in hole-doped IrNiOx core–shell electrocatalysts. Nat. Catal. 1, 841–851 (2018).

    Google Scholar

  59. Bergmann, A. et al. Unified structural motifs of the catalytically active state of Co(oxyhydr)oxides during the electrochemical oxygen evolution reaction. Nat. Catal. 1, 711–719 (2018).

    Google Scholar

  60. Beermann, V. et al. Real-time imaging of activation and degradation of carbon supported octahedral Pt–Ni alloy fuel cell catalysts at the nanoscale using in situ electrochemical liquid cell STEM. Energy Environ. Sci. 12, 2476–2485 (2019).

    Google Scholar

  61. Fabbri, E., Abbott, D. F., Nachtegaal, M. & Schmidt, T. J. Operando X-ray absorption spectroscopy: a powerful tool toward water splitting catalyst development. Curr. Opin. Electrochem. 5, 20–26 (2017).

    Google Scholar

  62. Hsu, S.-H. et al. An earth-abundant catalyst-based seawater photoelectrolysis system with 17.9% solar-to-hydrogen efficiency. Adv. Mater. 30, 1707261 (2018). This study uses density functional theory and experimental analysis to design and test a transition metal hexacyanometallate–cobalt–carbonate/NiMoS system for selective O2 evolution. The integrated system achieves a solar-to-hydrogen efficiency of 17.9% in seawater at neutral pH.

    Google Scholar

  63. Zeng, M. & Li, Y. Recent advances in heterogeneous electrocatalysts for the hydrogen evolution reaction. J. Mater. Chem. A 3, 14942–14962 (2015).

    Google Scholar

  64. Vos, J. G., Wezendonk, T. A., Jeremiasse, A. W. & Koper, M. T. M. MnOx/IrOx as selective oxygen evolution electrocatalyst in acidic chloride solution. J. Am. Chem. Soc. 140, 10270–10281 (2018). This report demonstrates that deposition of MnOx onto IrOx decreases the ClER selectivity of the system in the presence of 30 mM Cl from 86% to less than 7%, making it a highly OER-selective catalyst.

    Google Scholar

  65. Izumiya, K. et al. Anodically deposited manganese oxide and manganese-tungsten oxide electrodes for oxygen evolution from seawater. Electrochim. Acta 43, 3303–3312 (1998).

    Google Scholar

  66. Fujimura, K. et al. Anodically deposited manganese-molybdenum oxide anodes with high selectivity for evolving oxygen in electrolysis of seawater. J. Appl. Electrochem. 29, 765–771 (1999).

    Google Scholar

  67. Fujimura, K. et al. Oxygen evolution on manganese-molybdenum oxide anodes in seawater electrolysis. Mater. Sci. Eng. A 267, 254–259 (1999).

    Google Scholar

  68. Fujimura, K. et al. The durability of manganese–molybdenum oxide anodes for oxygen evolution in seawater electrolysis. Electrochim. Acta 45, 2297–2303 (2000).

    Google Scholar

  69. El-Moneim, A. A., Kumagai, N., Asami, K. & Hashimoto, K. New nanocrystallinemanganese-molybdenum-tin oxdie anodes for oxygen evolution in seatwater electrolysis. ECS Trans. 1, 491–497 (2006).

    Google Scholar

  70. Matsui, T. et al. Anodically deposited Mn-Mo-W oxide anodes for oxygen evolution in seawater electrolysis. J. Appl. Electrochem. 32, 993–1000 (2002).

    Google Scholar

  71. El-Moneim, A. A. Mn-Mo-W-oxide anodes for oxygen evolution during seawater electrolysis for hydrogen production: effect of repeated anodic deposition. Int. J. Hydrog. Energy 36, 13398–13406 (2011).

    Google Scholar

  72. Abdel Ghany, N. A., Kumagai, N., Meguro, S., Asami, K. & Hashimoto, K. Oxygen evolution anodes composed of anodically deposited Mn-Mo-Fe oxides for seawater electrolysis. Electrochim. Acta 48, 21–28 (2002).

    Google Scholar

  73. Kato, Z., Bhattarai, J., Kumagai, N., Izumiya, K. & Hashimoto, K. Durability enhancement and degradation of oxygen evolution anodes in seawater electrolysis for hydrogen production. Appl. Surf. Sci. 257, 8230–8236 (2011).

    Google Scholar

  74. Kato, Z. et al. Electrochemical characterization of degradation of oxygen evolution anode for seawater electrolysis. Electrochim. Acta 116, 152–157 (2014).

    Google Scholar

  75. Kato, Z. et al. The influence of coating solution and calcination condition on the durability of Ir1-xSnxO2/Ti anodes for oxygen evolution. Appl. Surf. Sci. 388, 640–644 (2016).

    Google Scholar

  76. Obata, K. & Takanabe, K. A Permselective CeOx coating to improve the stability of oxygen evolution electrocatalysts. Angew. Chem. Int. Ed. 57, 1616–1620 (2018).

    Google Scholar

  77. Balaji, R. et al. An alternative approach to selective sea water oxidation for hydrogen production. Electrochem. commun. 11, 1700–1702 (2009).

    MathSciNet Google Scholar

  78. Lu, X. et al. A sea-change: manganese doped nickel/nickel oxide electrocatalysts for hydrogen generation from seawater. Energy Environ. Sci. 11, 1898–1910 (2018). This study demonstrates a highly active HER catalyst electrode which exhibits Pt-like performances in both neutral electrolytes and natural seawater. The Mn doped NiO/Ni heterostructured electrode was formed by pyrolysing a Mn-MOF/Ni-F precursor in an inert environment.

    Google Scholar

  79. Bard, A. J., Parsons, R. & Jordan, J. Standard Potentials in Aqueous Solution (Routledge, 1985).

  80. Nørskov, J. K. et al. Trends in the exchange current for hydrogen evolution. J. Electrochem. Soc. 152, J23 (2005).

    Google Scholar

  81. Zheng, Y., Jiao, Y., Jaroniec, M. & Qiao, S. Z. Advancing the electrochemistry of the hydrogen-evolution reaction through combining experiment and theory. Angew. Chem. Int. Ed. 54, 52–65 (2015).

    Google Scholar

  82. Dinh, C.-T. et al. Multi-site electrocatalysts for hydrogen evolution in neutral media by destabilization of water molecules. Nat. Energy 4, 107–114 (2019).

    Google Scholar

  83. Song, L. J. & Meng, H. M. Effect of carbon content on Ni-Fe-C electrodes for hydrogen evolution reaction in seawater. Int. J. Hydrog. Energy 35, 10060–10066 (2010).

    Google Scholar

  84. Miao, J. et al. Hierarchical Ni-Mo-S nanosheets on carbon fiber cloth: A flexible electrode for efficient hydrogen generation in neutral electrolyte. Sci. Adv. 1, e1500259 (2015).

    Google Scholar

  85. Schalenbach, M. et al. Gas permeation through nafion. Part 1: measurements. J. Phys. Chem. C. 119, 25145–25155 (2015).

    Google Scholar

  86. Li, H., Tang, Q., He, B. & Yang, P. Robust electrocatalysts from an alloyed Pt-Ru-M (M = Cr, Fe, Co, Ni, Mo)-decorated Ti mesh for hydrogen evolution by seawater splitting. J. Mater. Chem. A 4, 6513–6520 (2016).

    Google Scholar

  87. Golgovici, F. et al. Ni–Mo alloy nanostructures as cathodic materials for hydrogen evolution reaction during seawater electrolysis. Chem. Pap. 72, 1889–1903 (2018).

    Google Scholar

  88. Zhang, Y., Li, P., Yang, X., Fa, W. & Ge, S. High-efficiency and stable alloyed nickel based electrodes for hydrogen evolution by seawater splitting. J. Alloy. Compd. 732, 248–256 (2018).

    Google Scholar

  89. Zheng, J., Zhao, Y., Xi, H. & Li, C. Seawater splitting for hydrogen evolution by robust electrocatalysts from secondary M (M = Cr, Fe, Co, Ni, Mo) incorporated Pt. RSC Adv. 8, 9423–9429 (2018).

    Google Scholar

  90. Raj, I. A. & Vasu, K. I. Transition metal-based hydrogen electrodes in alkaline solution — electrocatalysis on nickel based binary alloy coatings. J. Appl. Electrochem. 20, 32–38 (1990).

    Google Scholar

  91. Esposito, D. V. Membrane-coated electrocatalysts - an alternative approach to achieving stable and tunable electrocatalysis. ACS Catal. 8, 457–465 (2018).

    Google Scholar

  92. Vos, J. G. & Koper, M. T. M. Measurement of competition between oxygen evolution and chlorine evolution using rotating ring-disk electrode voltammetry. J. Electroanal. Chem. 819, 260–268 (2018). This report investigates the selectivity between chlorine evolution and oxygen evolution in aqueous media. Using a new method to quickly study chlorine evolution rates the authors demonstrate that oxygen evolution and chlorine evolution proceed independently on a glassy carbon supported IrOx catalyst.

    Google Scholar

  93. Lindbergh, G. & Simonsson, D. The effect of chromate addition on cathodic reduction of hypochlorite in hydroxide and chlorate solutions. J. Electrochem. Soc. 137, 3094–3099 (2006).

    Google Scholar

  94. Endrődi, B. et al. Towards sustainable chlorate production: The effect of permanganate addition on current efficiency. J. Clean. Prod. 182, 529–537 (2018).

    Google Scholar

  95. Ma, Y. Y. et al. Highly efficient hydrogen evolution from seawater by a low-cost and stable CoMoP@C electrocatalyst superior to Pt/C. Energy Environ. Sci. 10, 788–798 (2017).

  96. Kim, K., Kim, H., Lim, J. H. & Lee, S. J. Development of a desalination membrane bioinspired by mangrove roots for spontaneous filtration of sodium ions. ACS Nano 10, 11428–11433 (2016).

    Google Scholar

  97. Kumar, A., Phillips, K. R., Thiel, G. P., Schröder, U. & Lienhard, J. H. Direct electrosynthesis of sodium hydroxide and hydrochloric acid from brine streams. Nat. Catal. 2, 106–113 (2019).

    Google Scholar

  98. Schiermeier, Q., Tollefson, J., Scully, T., Witze, A. & Morton, O. Energy alternatives: electricity without carbon. Nature 454, 816–823 (2008).

    Google Scholar

  99. Gao, S. et al. Electrocatalytic H2 production from seawater over Co, N-codoped nanocarbons. Nanoscale 7, 2306–2316 (2015).

    Google Scholar

  100. Ma, Y. Y. et al. Highly efficient hydrogen evolution from seawater by a low-cost and stable CoMoP@C electrocatalyst superior to Pt/C. Energy Environ. Sci. 10, 788–798 (2017).

    Google Scholar

  101. Zhao, Y., Tang, Q., He, B. & Yang, P. Carbide decorated carbon nanotube electrocatalyst for high-efficiency hydrogen evolution from seawater. RSC Adv. 6, 93267–93274 (2016).

    Google Scholar

  102. Jin, H. et al. Single-crystal nitrogen-rich two-dimensional Mo5N6 nanosheets for efficient and stable seawater splitting. ACS Nano 12, 12761–12769 (2018).

    Google Scholar

  103. Sun, Y. et al. Electrodeposited cobalt-sulfide catalyst for electrochemical and photoelectrochemical hydrogen generation from water. J. Am. Chem. Soc. 135, 17699–17702 (2013).

    Google Scholar

  104. Zhao, Y., Jin, B., Vasileff, A., Jiao, Y. & Qiao, S. Interfacial nickel nitride/sulfide as a bifunctional electrode for highly efficient overall water/seawater electrolysis. J. Mater. Chem. A 7, 8117–8121 (2019). This study describes a bifunctional NiNS electrocatalyst for overall water splitting near neutral pH and in seawater.

    Google Scholar

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Electrolysis of low-grade and saline surface water (2024)
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