Fuel Production from Seawater and Fuel Cells Using Seawater.

Seawater is the most abundant resource on our planet and fuel production from seawater has the notable advantage that it would not compete with growing demands for pure water. This Review focuses on the production of fuels from seawater and their direct use in fuel cells. Electrolysis of seawater under appropriate conditions affords hydrogen and dioxygen with 100 % faradaic efficiency without oxidation of chloride. Photoelectrocatalytic production of hydrogen from seawater provides a promising way to produce hydrogen with low cost and high efficiency. Microbial solar cells (MSCs) that use biofilms produced in seawater can generate electricity from sunlight without additional fuel because the products of photosynthesis can be utilized as electrode reactants, whereas the electrode products can be utilized as photosynthetic reactants. Another important source for hydrogen is hydrogen sulfide, which is abundantly found in Black Sea deep water. Hydrogen produced by electrolysis of Black Sea deep water can also be used in hydrogen fuel cells. Production of a fuel and its direct use in a fuel cell has been made possible for the first time by a combination of photocatalytic production of hydrogen peroxide from seawater and dioxygen in the air and its direct use in one-compartment hydrogen peroxide fuel cells to obtain electric power.

[1]  Minglong Zhang,et al.  Photoelectrochemical cells for solar hydrogen production: current state of promising photoelectrodes, methods to improve their properties, and outlook , 2013 .

[2]  H. Beyenal,et al.  Multiple cathodic reaction mechanisms in seawater cathodic biofilms operating in sediment microbial fuel cells. , 2014, ChemSusChem.

[3]  Vinod M. Janardhanan,et al.  A model-based understanding of solid-oxide electrolysis cells (SOECs) for syngas production by H2O/CO2 co-electrolysis , 2015 .

[4]  K. Karlin,et al.  Hydrogen Peroxide as a Sustainable Energy Carrier: Electrocatalytic Production of Hydrogen Peroxide and the Fuel Cell. , 2012, Electrochimica acta.

[5]  A. Raj,et al.  A detailed reaction mechanism for hydrogen production via hydrogen sulphide (H2S) thermolysis and oxidation , 2016 .

[6]  F. Williams,et al.  Development of an Electrochemical Acidification Cell for the Recovery of CO2 and H2 from Seawater , 2011 .

[7]  S. Trasatti Electrocatalysis in the anodic evolution of oxygen and chlorine , 1984 .

[8]  R. Tunold,et al.  The corrosion of magnesium in aqueous solution containing chloride ions , 1977 .

[9]  Deepak Pant,et al.  Recent advances in the use of different substrates in microbial fuel cells toward wastewater treatment and simultaneous energy recovery , 2016 .

[10]  F. Williams,et al.  Development of an Electrolytic Cation Exchange Module for the Simultaneous Extraction of Carbon Dioxide and Hydrogen Gas from Natural Seawater , 2017 .

[11]  A. Melis,et al.  Solar energy conversion efficiencies in photosynthesis: Minimizing the chlorophyll antennae to maximize efficiency , 2009 .

[12]  Qiang Sun,et al.  High-temperature electrolysis of synthetic seawater using solid oxide electrolyzer cells , 2017 .

[13]  K. Ohkubo,et al.  Much enhanced catalytic reactivity of cobalt chlorin derivatives on two-electron reduction of dioxygen to produce hydrogen peroxide. , 2015, Inorganic chemistry.

[14]  G. Naterer,et al.  Electrochemical analysis of seawater electrolysis with molybdenum-oxo catalysts , 2013 .

[15]  Tao Yu,et al.  Solar hydrogen generation from seawater with a modified BiVO4 photoanode , 2011 .

[16]  Yusuke Yamada,et al.  Seawater usable for production and consumption of hydrogen peroxide as a solar fuel , 2016, Nature Communications.

[17]  Frances A. Houle,et al.  Particle suspension reactors and materials for solar-driven water splitting , 2015 .

[18]  Kaiqiang Liu,et al.  Construction of inorganic-organic 2D/2D WO₃/g-C₃N₄ nanosheet arrays toward efficient photoelectrochemical splitting of natural seawater. , 2016, Physical chemistry chemical physics : PCCP.

[19]  D. R. Bond,et al.  Electrode-Reducing Microorganisms That Harvest Energy from Marine Sediments , 2002, Science.

[20]  S. Ichikawa Photoelectrocatalytic production of hydrogen from natural seawater under sunlight , 1997 .

[21]  J. Lemmon,et al.  The co-electrolysis of CO2–H2O to methane via a novel micro-tubular electrochemical reactor , 2017 .

[22]  N. Kim,et al.  Sunlight-driven sustainable production of hydrogen peroxide using a CdS–graphene hybrid photocatalyst , 2017 .

[23]  Alessandro Liberale,et al.  Floating microbial fuel cells as energy harvesters for signal transmission from natural water bodies , 2017 .

[24]  Xingjun Liu,et al.  Hydrogen generation from hydrolysis of activated Al-Bi, Al-Sn powders prepared by gas atomization method , 2017 .

[25]  Tong Liu,et al.  High temperature solid oxide H2O/CO2 co-electrolysis for syngas production , 2017 .

[26]  Mogens Bjerg Mogensen,et al.  High temperature electrolysis in alkaline cells, solid proton conducting cells, and solid oxide cells. , 2014, Chemical reviews.

[27]  Kun Liu,et al.  Producing hydrogen in an aqueous NaCl solution by the hydrolysis of metallic couples of low-grade magnesium scrap and noble metal net , 2009 .

[28]  Ze Yu,et al.  Recent advances in dye-sensitized photoelectrochemical cells for solar hydrogen production based on molecular components , 2015 .

[29]  Ashlynn Suzanne Stillwell,et al.  Quantifying Energy and Water Savings in the U.S. Residential Sector. , 2016, Environmental science & technology.

[30]  A. Demirbas Hydrogen Sulfide from the Black Sea for Hydrogen Production , 2009 .

[31]  Craig Eldershaw,et al.  CO2 extraction from seawater using bipolar membrane electrodialysis , 2012 .

[32]  B Erable,et al.  Marine floating microbial fuel cell involving aerobic biofilm on stainless steel cathodes. , 2013, Bioresource technology.

[33]  James R. McKone,et al.  Solar water splitting cells. , 2010, Chemical reviews.

[34]  L. Ouyang,et al.  Excellent hydrolysis performances of Mg3RE hydrides , 2013 .

[35]  Shunsuke Tanaka,et al.  Carbon Nitride-Aromatic Diimide-Graphene Nanohybrids: Metal-Free Photocatalysts for Solar-to-Hydrogen Peroxide Energy Conversion with 0.2% Efficiency. , 2016, Journal of the American Chemical Society.

[36]  J. Uan,et al.  Effects of concentrations of NaCl and organic acid on generation of hydrogen from magnesium metal scrap , 2012 .

[37]  G. Song,et al.  Corrosion mechanisms of magnesium alloys , 1999 .

[38]  J. Chen,et al.  A review of high temperature co-electrolysis of H2O and CO2 to produce sustainable fuels using solid oxide electrolysis cells (SOECs): advanced materials and technology. , 2017, Chemical Society reviews.

[39]  Zhiliang Wang,et al.  Photoelectrocatalytic Water Splitting: Significance of Cocatalysts, Electrolyte, and Interfaces , 2017 .

[40]  Jiyu He,et al.  The preparation of Mg-based hydro-reactive materials and their reactive properties in seawater , 2011 .

[41]  Eiji Akiyama,et al.  Anodically deposited manganese-molybdenum oxide anodes with high selectivity for evolving oxygen in electrolysis of seawater , 1999 .

[42]  M. Melaina,et al.  Production of Fischer–Tropsch liquid fuels from high temperature solid oxide co-electrolysis units , 2012 .

[43]  Hubert H. Girault,et al.  Coplanar Interdigitated Band Electrodes for Electrosynthesis Part 4 : Application to Sea Water Electrolysis , 1998 .

[44]  Xin Wang,et al.  Enhanced oxygen reducing biocathode electroactivity by using sediment extract as inoculum. , 2017, Bioelectrochemistry.

[45]  A. Sanli,et al.  A novel H2S/H2O2 fuel cell operating at the temperature of 298 K , 2013 .

[46]  Jean Jouzel,et al.  Deuterium excess in an East Antarctic ice core suggests higher relative humidity at the oceanic surface during the last glacial maximum , 1982, Nature.

[47]  B. Lever,et al.  The production of hypochlorite by direct electrolysis of sea water: Electrode materials and design of cells for the process , 1963 .

[48]  K. Hashimoto,et al.  The influence of coating solution and calcination condition on the durability of Ir1-xSnxO2/Ti anodes for oxygen evolution , 2016 .

[49]  Paul R. Ehrlich,et al.  Human Appropriation of Renewable Fresh Water , 1996, Science.

[50]  S. Fukuzumi,et al.  Hydrogen Peroxide used as a Solar Fuel in One‐Compartment Fuel Cells , 2016 .

[51]  Geraint Williams,et al.  Inhibition of magnesium localised corrosion in chloride containing electrolyte , 2010 .

[52]  C. Vörösmarty,et al.  Global water resources: vulnerability from climate change and population growth. , 2000, Science.

[53]  R. Schwarzenbach,et al.  The Challenge of Micropollutants in Aquatic Systems , 2006, Science.

[54]  Min Zhu,et al.  Hydrogen generation by hydrolysis of MgH2 and enhanced kinetics performance of ammonium chloride introducing , 2015 .

[55]  P. Strasser,et al.  Design Criteria, Operating Conditions, and Nickel-Iron Hydroxide Catalyst Materials for Selective Seawater Electrolysis. , 2016, ChemSusChem.

[56]  N. Hanley,et al.  Understanding the distribution of economic benefits from improving coastal and marine ecosystems. , 2017, The Science of the total environment.

[57]  T. Veziroglu,et al.  A parametric investigation of hydrogen energy potential based on H2S in Black Sea deep waters , 2007 .

[58]  Can Li,et al.  Cl− making overall water splitting possible on TiO2-based photocatalysts , 2014 .

[59]  Hans-Christian Steen-Larsen,et al.  Deuterium excess in marine water vapor: Dependency on relative humidity and surface wind speed during evaporation , 2014 .

[60]  J. Kruger,et al.  Corrosion of magnesium , 1993 .

[61]  D. Sangeetha,et al.  Studies on polymer modified metal oxide anode for oxygen evolution reaction in saline water , 2013 .

[62]  S. Fukuzumi,et al.  Photocatalytic production of hydrogen peroxide from water and dioxygen using cyano-bridged polynuclear transition metal complexes as water oxidation catalysts , 2016 .

[63]  Jiangwen Liu,et al.  Enhanced Hydrogen Storage Kinetics and Stability by Synergistic Effects of in Situ Formed CeH2.73 and Ni in CeH2.73-MgH2‑Ni Nanocomposites , 2014 .

[64]  Y. Arata,et al.  Spectroscopic Characterization and the pH Dependence of Bactericidal Activity of the Aqueous Chlorine Solution , 1998 .

[65]  S. Fukuzumi,et al.  Production of hydrogen peroxide by combination of semiconductor-photocatalysed oxidation of water and photocatalytic two-electron reduction of dioxygen , 2016 .

[66]  M. Vlaskin,et al.  Hydrogen generation by oxidation of coarse aluminum in low content alkali aqueous solution under intensive mixing , 2016 .

[67]  Can Li,et al.  The Institute of Chemistry of Great Britain and Ireland. Proceedings of the Council. (August–September, 1920) , 2022 .

[68]  J. E. Bennett Electrodes for generation of hydrogen and oxygen from seawater , 1980 .

[69]  K. Ohkubo,et al.  Dual function photocatalysis of cyano-bridged heteronuclear metal complexes for water oxidation and two-electron reduction of dioxygen to produce hydrogen peroxide as a solar fuel. , 2017, Chemical Communications.

[70]  K. Ohkubo,et al.  Efficient two-electron reduction of dioxygen to hydrogen peroxide with one-electron reductants with a small overpotential catalyzed by a cobalt chlorin complex. , 2013, Journal of the American Chemical Society.

[71]  Tae Hee Cho,et al.  Fabrication of Mg-Ni-Sn alloys for fast hydrogen generation in seawater , 2017 .

[72]  M. Kummu,et al.  The world’s road to water scarcity: shortage and stress in the 20th century and pathways towards sustainability , 2016, Scientific Reports.

[73]  Yusuke Yamada,et al.  Efficient Photocatalytic Production of Hydrogen Peroxide from Water and Dioxygen with Bismuth Vanadate and a Cobalt(II) Chlorin Complex , 2016 .

[74]  Q. Tang,et al.  Carbide decorated carbon nanotube electrocatalyst for high-efficiency hydrogen evolution from seawater , 2016 .

[75]  Frederick W. Williams,et al.  Feasibility of CO2 Extraction from Seawater and Simultaneous Hydrogen Gas Generation Using a Novel and Robust Electrolytic Cation Exchange Module Based on Continuous Electrodeionization Technology , 2014 .

[76]  Joshua M. Spurgeon,et al.  Solar hydrogen production from seawater vapor electrolysis , 2016 .

[77]  P. Marquaire,et al.  Kinetic Study of the Pyrolysis of H 2 S , 2003 .

[78]  Q. Tang,et al.  Robust electrocatalysts from an alloyed Pt–Ru–M (M = Cr, Fe, Co, Ni, Mo)-decorated Ti mesh for hydrogen evolution by seawater splitting , 2016 .

[79]  J. Maiz,et al.  Tailoring thermal conductivity via three-dimensional porous alumina , 2016, Scientific Reports.

[80]  Nathan S Lewis,et al.  Developing a scalable artificial photosynthesis technology through nanomaterials by design. , 2016, Nature nanotechnology.

[81]  Thorsten Wagener,et al.  Enhanced groundwater recharge rates and altered recharge sensitivity to climate variability through subsurface heterogeneity , 2017, Proceedings of the National Academy of Sciences.

[82]  Hui Wang,et al.  Enhanced Hydrogen Generation Properties of MgH2-Based Hydrides by Breaking the Magnesium Hydroxide Passivation Layer , 2015 .

[83]  J. Zheng Seawater splitting for high-efficiency hydrogen evolution by alloyed PtNi x electrocatalysts , 2017 .

[84]  Q. Tang,et al.  Robust and stable ruthenium alloy electrocatalysts for hydrogen evolution by seawater splitting , 2016 .

[85]  S. Fukuzumi,et al.  High and robust performance of H2O2 fuel cells in the presence of scandium ion , 2015 .

[86]  I. Ture,et al.  Industrial extraction pilot plant for stripping H2S gas from Black Sea water , 2008 .

[87]  V. Ramanathan,et al.  Aerosols, Climate, and the Hydrological Cycle , 2001, Science.

[88]  P. Fornasiero,et al.  Photocatalytic Hydrogen Production: A Rift into the Future Energy Supply , 2017 .

[89]  L. Ouyang,et al.  Improved hydrolysis properties of Mg3RE hydrides alloyed with Ni , 2014 .

[90]  B. Filiz,et al.  Hydrogen production by the hydrolysis of milled waste magnesium scraps in nickel chloride solutions and nickel chloride added in Marmara Sea and Aegean Sea Water , 2015 .

[91]  S. Fukuzumi,et al.  Thermal and Photocatalytic Production of Hydrogen Peroxide and its Use in Hydrogen Peroxide Fuel Cells , 2014 .

[92]  T. Nejat Veziroglu,et al.  Hydrogen from hydrogen sulphide in Black Sea , 2007 .

[93]  Peng Wang,et al.  In situ glass antifouling using Pt nanoparticle coating for periodic electrolysis of seawater , 2015 .

[94]  S. Fukuzumi,et al.  Production of hydrogen peroxide as a sustainable solar fuel from water and dioxygen , 2013 .

[95]  Sylvia Gildemyn,et al.  A critical revisit of the key parameters used to describe microbial electrochemical systems , 2014 .

[96]  D. Macfarlane,et al.  Enhanced photo-electrochemical water oxidation on MnOx in buffered organic/inorganic electrolytes , 2015 .

[97]  Javier J. Concepcion,et al.  Chloride-assisted catalytic water oxidation. , 2014, Chemical communications.

[98]  F. Williams,et al.  Development of an Electrochemical Acidification Cell for the Recovery of CO2 and H2 from Seawater II. Evaluation of the Cell by Natural Seawater , 2012 .

[99]  L. Ouyang,et al.  Low-cost method for sodium borohydride regeneration and the energy efficiency of its hydrolysis and regeneration process , 2014 .

[100]  H. Beyenal,et al.  Evaluation of long-term performance of sediment microbial fuel cells and the role of natural resources , 2017 .

[101]  L. Ouyang,et al.  Enhanced hydrolysis properties and energy efficiency of MgH2-base hydrides , 2016 .

[102]  G. Frankel,et al.  Effect of impurities on the enhanced catalytic activity for hydrogen evolution in high purity magnesium , 2015 .

[103]  A. Veziroğlu,et al.  An assessment of electrolytic hydrogen production from H2S in Black Sea waters , 2011 .

[104]  Frances A. Houle,et al.  Life-cycle net energy assessment of large-scale hydrogen production via photoelectrochemical water splitting , 2014 .

[105]  Ib Chorkendorff,et al.  Strategies for stable water splitting via protected photoelectrodes. , 2017, Chemical Society reviews.

[106]  M. Rahimnejad,et al.  Sediment microbial fuel cells as a new source of renewable and sustainable energy: present status and future prospects , 2015 .

[107]  Ramees K. Rahman,et al.  Kinetic Simulations of H2 Production from H2S Pyrolysis in Sulfur Recovery Units Using a Detailed Reaction Mechanism , 2016 .

[108]  Kaiqiang Liu,et al.  Efficient and Stable Photoelectrochemical Seawater Splitting with TiO2@g-C3N4 Nanorod Arrays Decorated by Co-Pi , 2015 .

[109]  R. Dittmeyer,et al.  An electrocatalytic membrane-assisted process for hydrogen production from H2S in Black Sea: Preliminary results , 2015 .

[110]  A. Kudo,et al.  Heterogeneous photocatalyst materials for water splitting. , 2009, Chemical Society reviews.

[111]  N. Birbilis,et al.  Controlling factors in localised corrosion morphologies observed for magnesium immersed in chloride containing electrolyte. , 2015, Faraday discussions.

[112]  K. Cheng,et al.  Photo-enhanced salt-water splitting using orthorhombic Ag8SnS6 photoelectrodes in photoelectrochemical cells , 2016 .

[113]  S. Baykara,et al.  Production of hydrogen from hydrogen sulfide with perovskite type catalysts: LaMO3 , 2017 .

[114]  Yongjun Yuan,et al.  Metal-complex chromophores for solar hydrogen generation. , 2017, Chemical Society reviews.

[115]  P. Kamat Semiconductor Surface Chemistry as Holy Grail in Photocatalysis and Photovoltaics. , 2017, Accounts of chemical research.

[116]  Hyuk-Sang Kwon,et al.  Design of Mg–Ni alloys for fast hydrogen generation from seawater and their application in polymer electrolyte membrane fuel cells , 2016 .

[117]  L. Tender,et al.  Harvesting Energy from the Marine Sediment−Water Interface , 2001 .

[118]  S. Fukuzumi,et al.  Bottom-up and top-down methods to improve catalytic reactivity for photocatalytic production of hydrogen peroxide using a Ru-complex and water oxidation catalysts , 2015 .

[119]  Jarosław Milewski,et al.  Progress of the IAHE Nuclear Hydrogen Division on international hydrogen production programs , 2016 .

[120]  S. Fukuzumi Artificial photosynthesis for production of hydrogen peroxide and its fuel cells. , 2016, Biochimica et biophysica acta.

[121]  N. Birbilis,et al.  Evolution of hydrogen at dissolving magnesium surfaces , 2013 .