Towards practical implementation. Lomoth, R. Mimicking the electron donor side of Photosystem II in artificial photosynthesis. Jiao, F.
Shop with confidence
Nanostructured cobalt and manganese oxide clusters as efficient water oxidation catalysts. Peter, L. Kinetics of light-driven oxygen evolution at alpha-Fe2O3 electrodes. Le Formal, F. Passivating surface states on water splitting hematite photoanodes with alumina overlayers. Challenges and opportunities in light and electrical energy conversion.
Join Kobo & start eReading today
Pendlebury, S. Dynamics of photogenerated holes in nanocrystalline alpha-Fe2O3 electrodes for water oxidation probed by transient absorption spectroscopy. Wang, X. Trap states and carrier dynamics of TiO2 studied by photoluminescence spectroscopy under weak excitation condition. Subpicosecond interfacial charge separation in dye-sensitized nanocrystalline titanium dioxide films.
Haque, S. Parameters influencing charge recombination kinetics in dye-sensitized nanocrystalline titanium dioxide films. Ardo, S. Photodriven heterogeneous charge transfer with transition-metal compounds anchored to TiO2 semiconductor surfaces. Dare-Edwards, M.
Electrochemistry and photoelectrochemistry of iron III oxide. Faraday Trans.
Hanna, M. Solar conversion efficiency of photovoltaic and photoelectrolysis cells with carrier multiplication absorbers. Shockley, W. Detailed balance limit of efficiency of p—n junction solar cells. Chen, Z. Accelerating materials development for photoelectrochemical hydrogen production: Standards for methods, definitions, and reporting protocols. Ekins, P. Hydrogen Energy Earthscan, Download references. The authors thank J. Nolan and J. Correspondence to Yasuhiro Tachibana or Lionel Vayssieres. Reprints and Permissions.
Artificial photosynthesis for solar water-splitting. Nature Photon 6, — doi Download citation. Applied Catalysis B: Environmental Catalysis Today Advanced search. Skip to main content. Subjects Solar energy and photovoltaic technology. Abstract Hydrogen generated from solar-driven water-splitting has the potential to be a clean, sustainable and abundant energy source. Access through your institution. Buy or subscribe. Change institution. Rent or Buy article Get time limited or full article access on ReadCube. Figure 2: Structural designs of APS reaction processes.
Figure 3: New concepts of nanomaterial developments.
Figure 4: Photo-induced charge separation and recombination of a semiconductor photoanode. Figure 5: Vision of a sustainable hydrogen fuel community based on APS. References 1 Barber, J. Article Google Scholar 2 Blankenship, R. Article Google Scholar 5 Kronawitter, C.
Article Google Scholar 6 Maeda, K. Article Google Scholar 7 Tachibana, Y.
- The Days and Nights of Oliver Otus (The Birds: Six Bird Stories by Shelley J. Reeves Book 5).
- Redemption (Fallyn Book 1)?
- Sherlock Holmes Consulting Detective: Volume One!
- What is Kobo Super Points?;
- Immortal Ecstasy.
- Solar hydrogen generation : transition metal oxides in water photoelectrolysis!
- Nanomaterials for renewable hydrogen production, storage and utilization - ScienceDirect.
Article Google Scholar 8 Wasielewski, M. Article Google Scholar 9 Yin, Q. Article Google Scholar 13 Nocera, D. Article Google Scholar 17 Limburg, J. Article Google Scholar 19 Abe, R. Article Google Scholar 20 Gust, D. Article Google Scholar 23 Fukuzumi, S. Article Google Scholar 24 Kodis, G.
Article Google Scholar 25 Gust, D. Article Google Scholar 28 Maeda, K. Article Google Scholar 30 Chen, X. Article Google Scholar 31 Youngblood, W. Article Google Scholar 32 Brimblecombe, R. Article Google Scholar 33 Maeda, K. Article Google Scholar 36 Walter, M. Article Google Scholar 37 Sasaki, Y. Article Google Scholar 38 Tada, H. Article Google Scholar 42 Kubacka, A.
Article Google Scholar 43 Valdes, A.
Solar Hydrogen Generation: Transition Metal Oxides in Water Photoelectrolysis
Article Google Scholar 44 Xing, J. Article Google Scholar 45 Shen, S. Article Google Scholar 47 Tributsch, H. Article Google Scholar 48 Sahaym, U. Article Google Scholar 51 Vayssieres, L. Google Scholar 52 Zini, G. Google Scholar 53 Grimes, C. Google Scholar 54 Rajeshwar, K.
Google Scholar 55 Guo, J. Google Scholar 56 Chouhan, N. Google Scholar 57 Vayssieres, L.