PDF Publication Title:
Text from PDF Page: 067
Energies 2020, 13, 420 67 of 96 107. Miller, J.E.; Allendorf, M.D.; Diver, R.B.; Evans, L.R.; Siegel, N.P.; Stuecker, J.N. Metal oxide composites and structures for ultra-high temperature solar thermochemical cycles. J. Mater. Sci. 2008, 43, 4714–4728. [CrossRef] 108. Lorentzou,S.;Pagkoura,C.;Zygogianni,A.;Karagiannakis,G.;Konstandopoulos,A.G.Thermochemical cycles over redox structured reactors. Int. J. Hydrog. Energy 2017, 42, 19664–19682. [CrossRef] 109. LeGal,A.;Abanades,S.;Bion,N.;LeMercier,T.;Harlé,V.Reactivityofdopedceria-basedmixedoxides for solar thermochemical hydrogen generation via two-step water-splitting cycles. Energy Fuels 2013, 27, 6068–6078. [CrossRef] 110. LeGal,A.;Abanades,S.Dopantincorporationinceriaforenhancedwater-splittingactivityduringsolar thermochemical hydrogen generation. J. Phys. Chem. C 2012, 116, 13516–13523. [CrossRef] 111. Haeussler,A.;Abanades,S.;Jouannaux,J.;Drobek,M.;Ayral,A.;Julbe,A.Recentprogressonceriadoping and shaping strategies for solar thermochemical water and CO2 splitting cycles. Aims Mater. Sci. 2019, 6, 657–684. [CrossRef] 112. Muhich,C.;Steinfeld,A.PrinciplesofdopingceriaforthesolarthermochemicalredoxsplittingofH2Oand CO2. J. Mater. Chem. A 2017, 5, 15578–15590. [CrossRef] 113. Muhich,C.L.;Blaser,S.;Hoes,M.C.;Steinfeld,A.Comparingthesolar-to-fuelenergyconversionefficiency of ceria and perovskite based thermochemical redox cycles for splitting H2O and CO2. Int. J. Hydrog. Energy 2018, 43, 18814–18831. [CrossRef] 114. Lapp,J.;Davidson,J.H.;Lipin ́ski,W.Efficiencyoftwo-stepsolarthermochemicalnon-stoichiometricredox cycles withheat recovery. Energy 2012, 37, 591–600. [CrossRef] 115. Perkins,C.;Weimer,A.W.Likelynear-termsolar-thermalwatersplittingtechnologies.Int.J.Hydrog.Energy 2004, 29, 1587–1599. [CrossRef] 116. Charvin,P.;Stéphane,A.;Florent,L.;Gilles,F.Analysisofsolarchemicalprocessesforhydrogenproduction from water splitting thermochemical cycles. Energy Convers. Manag. 2008, 49, 1547–1556. [CrossRef] 117. Palumbo,R.;Lédé,J.;Boutin,O.;Ricart,E.E.;Steinfeld,A.;Möller,S.;Weidenkaff,A.;Fletcher,E.A.;Bielicki,J. The production of Zn from ZnO in a high-temperature solar decomposition quench process—I. The scientific framework for the process. Chem. Eng. Sci. 1998, 53, 2503–2517. [CrossRef] 118. Charvin,P.;Abanades,S.;Beche,E.;Lemont,F.;Flamant,G.Hydrogenproductionfrommixedceriumoxides via three-step water-splitting cycles. Solid State Ion. 2009, 180, 1003–1010. [CrossRef] 119. Liberatore,R.;Lanchi,M.;Giaconia,A.;Tarquini,P.Energyandeconomicassessmentofanindustrialplant for the hydrogen production by water-splitting through the sulfur-iodine thermochemical cycle powered by concentrated solar energy. Int. J. Hydrog. Energy 2012, 37, 9550–9565. [CrossRef] 120. Caple, K.; Kreider, P.; Auyeung, N.; Yokochi, A. Experimental modeling of hydrogen producing steps in a novel sulfur-sulfur thermochemical water splitting cycle. Int. J. Hydrog. Energy 2015, 40, 2484–2492. [CrossRef] 121. Yilmaz,F.;Selbas ̧,R.Thermodynamicperformanceassessmentofsolarbasedsulfur-iodinethermochemical cycle for hydrogen generation. Energy 2017, 140, 520–529. [CrossRef] 122. Naterer,G.F.;Suppiah,S.;Stolberg,L.;Lewis,M.;Wang,Z.;Daggupati,V.;Gabriel,K.;Dincer,I.;Rosen,M.A.; Spekkens, P.; et al. Canada’s program on nuclear hydrogen production and the thermochemical Cu-Cl cycle. Int. J. Hydrog. Energy 2010, 35, 10905–10926. [CrossRef] 123. Wang,Z.L.;Naterer,G.F.;Gabriel,K.S.;Gravelsins,R.;Daggupati,V.N.Comparisonofsulfur-iodineand copper-chlorine thermochemical hydrogen production cycles. Int. J. Hydrog. Energy 2010, 35, 4820–4830. [CrossRef] 124. Wang,Z.;Naterer,G.F.;Gabriel,K.S.;Secnik,E.;Gravelsins,R.;Daggupati,V.Thermaldesignofasolar hydrogen plant with a copper-chlorine cycle and molten salt energy storage. Int. J. Hydrog. Energy 2011, 36, 11258–11272. [CrossRef] 125. Naterer,G.F.;Gabriel,K.;Wang,Z.L.;Daggupati,V.N.;Gravelsins,R.Thermochemicalhydrogenproduction with a copper-chlorine cycle. I: Oxygen release from copper oxychloride decomposition. Int. J. Hydrog. Energy 2008, 33, 5439–5450. [CrossRef] 126. Balta,M.T.;Dincer,I.;Hepbasli,A.Energyandexergyanalysesofanewfour-stepcopper-chlorinecyclefor geothermal-based hydrogen production. Energy 2010, 35, 3263–3272. [CrossRef]PDF Image | Green Synthetic Fuels
PDF Search Title:
Green Synthetic FuelsOriginal File Name Searched:
energies-13-00420.pdfDIY PDF Search: Google It | Yahoo | Bing
NFT (Non Fungible Token): Buy our tech, design, development or system NFT and become part of our tech NFT network... More Info
IT XR Project Redstone NFT Available for Sale: NFT for high tech turbine design with one part 3D printed counter-rotating energy turbine. Be part of the future with this NFT. Can be bought and sold but only one design NFT exists. Royalties go to the developer (Infinity) to keep enhancing design and applications... More Info
Infinity Turbine IT XR Project Redstone Design: NFT for sale... NFT for high tech turbine design with one part 3D printed counter-rotating energy turbine. Includes all rights to this turbine design, including license for Fluid Handling Block I and II for the turbine assembly and housing. The NFT includes the blueprints (cad/cam), revenue streams, and all future development of the IT XR Project Redstone... More Info
Infinity Turbine ROT Radial Outflow Turbine 24 Design and Worldwide Rights: NFT for sale... NFT for the ROT 24 energy turbine. Be part of the future with this NFT. This design can be bought and sold but only one design NFT exists. You may manufacture the unit, or get the revenues from its sale from Infinity Turbine. Royalties go to the developer (Infinity) to keep enhancing design and applications... More Info
Infinity Supercritical CO2 10 Liter Extractor Design and Worldwide Rights: The Infinity Supercritical 10L CO2 extractor is for botanical oil extraction, which is rich in terpenes and can produce shelf ready full spectrum oil. With over 5 years of development, this industry leader mature extractor machine has been sold since 2015 and is part of many profitable businesses. The process can also be used for electrowinning, e-waste recycling, and lithium battery recycling, gold mining electronic wastes, precious metals. CO2 can also be used in a reverse fuel cell with nafion to make a gas-to-liquids fuel, such as methanol, ethanol and butanol or ethylene. Supercritical CO2 has also been used for treating nafion to make it more effective catalyst. This NFT is for the purchase of worldwide rights which includes the design. More Info
NFT (Non Fungible Token): Buy our tech, design, development or system NFT and become part of our tech NFT network... More Info
Infinity Turbine Products: Special for this month, any plans are $10,000 for complete Cad/Cam blueprints. License is for one build. Try before you buy a production license. May pay by Bitcoin or other Crypto. Products Page... More Info
| CONTACT TEL: 608-238-6001 Email: greg@infinityturbine.com | RSS | AMP |