- -

Lanthanum tungstate membranes for H-2 extraction and CO2 utilization: Fabrication strategies based on sequential tape casting and plasma-spray physical vapor deposition

RiuNet: Repositorio Institucional de la Universidad Politécnica de Valencia

Compartir/Enviar a

Citas

Estadísticas

  • Estadisticas de Uso

Lanthanum tungstate membranes for H-2 extraction and CO2 utilization: Fabrication strategies based on sequential tape casting and plasma-spray physical vapor deposition

Mostrar el registro sencillo del ítem

Ficheros en el ítem

Thumbnail
Nombre: Ivanova;Deibert;M ...
Tamaño: 1.344Mb
Formato: PDF
Descripción: Versión del Autor.
Abrir
[Cerrado]
Nombre: 36_2019_Lanthanum ...
Tamaño: 3.144Mb
Formato: PDF
Descripción: Versión editorial
Solicitar una copia al autor
dc.contributor.author Ivanova, M. E. es_ES
dc.contributor.author Deibert, W. es_ES
dc.contributor.author Marcano, D. es_ES
dc.contributor.author Escolástico Rozalén, Sonia es_ES
dc.contributor.author Mauer, G. es_ES
dc.contributor.author Meulenberg, W. A. es_ES
dc.contributor.author Bram, M. es_ES
dc.contributor.author Serra Alfaro, José Manuel es_ES
dc.contributor.author Vassen, R. es_ES
dc.contributor.author Guillon, O. es_ES
dc.date.accessioned 2021-02-04T04:32:12Z
dc.date.available 2021-02-04T04:32:12Z
dc.date.issued 2019-07-15 es_ES
dc.identifier.issn 1383-5866 es_ES
dc.identifier.uri http://hdl.handle.net/10251/160683
dc.description.abstract [EN] In the context of energy conversion efficiency and decreasing greenhouse gas emissions from power generation and energy-intensive industries, membrane technologies for H-2 extraction and CO2 capture and utilization become pronouncedly important. Mixed protonic-electronic conducting ceramic membranes are hence attractive for the pre-combustion integrated gasification combined cycle, specifically in the water gas shift and H-2 separation process, and also for designing catalytic membrane reactors. This work presents the fabrication, microstructure and functional properties of Lanthanum tungstates (La28-xW4+xO54+delta, LaWO) asymmetric membranes supported on porous ceramic and porous metallic substrates fabricated by means of the sequential tape casting route and plasma spray-physical vapor deposition (PS-PVD). Pure LaWO and W site substituted LaWO were employed as membrane materials due to the promising combination of properties: appreciable mixed protonic-electronic conductivity at intermediate temperatures and reducing atmospheres, good sinterability and noticeable chemical stability under harsh operating conditions. As substrate materials porous LaWO (non-substituted), MgO and Crofer22APU stainless steel were used to support various LaWO membrane layers. The effect of fabrication parameters and material combinations on the assemblies' microstructure, LaWO phase formation and gas tightness of the functional layers was explored along with the related fabrication challenges for shaping LaWO layers with sufficient quality for further practical application. The two different fabrication strategies used in the present work allow for preparing all-ceramic and ceramic-metallic assemblies with LaWO membrane layers with thicknesses between 25 and 60 mu m and H-2 flux of ca. 0.4 ml/min cm(2) measured at 825 degrees C in 50 vol% H-2 in He dry feed and humid Ar sweep configuration. Such a performance is an exceptional achievement for the LaWO based H-2 separation membranes and it is well comparable with the H-2 flux reported for other newly developed dual phase cer-cer and cer-met membranes. es_ES
dc.description.sponsorship ProtOMem Project under the BMBF grant 03SF0537 is gratefully acknowledged. Furthermore, the authors thank Ralf Laufs for his assistance in operating the PS-PVD facility. Dr. A. Schwedt from the Central Facility for Electron Microscopy (Gemeinschaftslabor fur Elektronenmikroskopie GFE), RWTH Aachen University is acknowledged for performing the EBSD analysis on the PS-PVD samples. es_ES
dc.language Inglés es_ES
dc.publisher Elsevier es_ES
dc.relation.ispartof Separation and Purification Technology es_ES
dc.rights Reconocimiento - No comercial - Sin obra derivada (by-nc-nd) es_ES
dc.subject Solid state proton conductors es_ES
dc.subject Ceramic mixed protonic-electronic conductors es_ES
dc.subject Lanthanum tungstate membranes es_ES
dc.subject Metal supported ceramic membranes es_ES
dc.subject Crofer22APU es_ES
dc.subject H-2 separation es_ES
dc.subject CO2 utilization es_ES
dc.subject Membrane reactors es_ES
dc.subject Tape casting es_ES
dc.subject Plasma spray-physical vapor deposition PS-PVD es_ES
dc.title Lanthanum tungstate membranes for H-2 extraction and CO2 utilization: Fabrication strategies based on sequential tape casting and plasma-spray physical vapor deposition es_ES
dc.type Artículo es_ES
dc.identifier.doi 10.1016/j.seppur.2019.03.015 es_ES
dc.relation.projectID info:eu-repo/grantAgreement/BMBF//03SF0537/ es_ES
dc.rights.accessRights Abierto es_ES
dc.contributor.affiliation Universitat Politècnica de València. Instituto Universitario Mixto de Tecnología Química - Institut Universitari Mixt de Tecnologia Química es_ES
dc.description.bibliographicCitation Ivanova, ME.; Deibert, W.; Marcano, D.; Escolástico Rozalén, S.; Mauer, G.; Meulenberg, WA.; Bram, M.... (2019). Lanthanum tungstate membranes for H-2 extraction and CO2 utilization: Fabrication strategies based on sequential tape casting and plasma-spray physical vapor deposition. Separation and Purification Technology. 219:100-112. https://doi.org/10.1016/j.seppur.2019.03.015 es_ES
dc.description.accrualMethod S es_ES
dc.relation.publisherversion https://doi.org/10.1016/j.seppur.2019.03.015 es_ES
dc.description.upvformatpinicio 100 es_ES
dc.description.upvformatpfin 112 es_ES
dc.type.version info:eu-repo/semantics/publishedVersion es_ES
dc.description.volume 219 es_ES
dc.relation.pasarela S\389513 es_ES
dc.contributor.funder Bundesministerium für Bildung und Forschung, Alemania es_ES
dc.description.references A.A. Evers, The hydrogen society, More than just a vision? ISBN 978-3-937863-31-3, Hydrogeit Verlag, 16727 Oberkraemer, Germany, 2010. es_ES
dc.description.references Deibert, W., Ivanova, M. E., Baumann, S., Guillon, O., & Meulenberg, W. A. (2017). Ion-conducting ceramic membrane reactors for high-temperature applications. Journal of Membrane Science, 543, 79-97. doi:10.1016/j.memsci.2017.08.016 es_ES
dc.description.references Arun C. Bose, Inorganic membranes for energy and environmental applications, Edt. A. C. Bose, ISBN: 978-0-387-34524-6, Springer Science+Business Media, LLC, 2009. es_ES
dc.description.references M. Marrony, H. Matsumoto, N. Fukatsu, M. Stoukides, Typical applications of proton ceramic cells: a way to market? in: M. Marrony (ed.), Proton-conducting ceramics. From fundamentals to applied research, by Pan Stanford Publishing Pte. Ltd., ISBN 978-981-4613-84-2, 2016. es_ES
dc.description.references Di Giorgio, P., & Desideri, U. (2016). Potential of Reversible Solid Oxide Cells as Electricity Storage System. Energies, 9(8), 662. doi:10.3390/en9080662 es_ES
dc.description.references A.L. Dicks, D.A.J. Rand, Fuel cell systems explained, ISBN: 9781118613528, John Wiley & Sons Ltd., 2018. es_ES
dc.description.references Zheng, Y., Wang, J., Yu, B., Zhang, W., Chen, J., Qiao, J., & Zhang, J. (2017). A review of high temperature co-electrolysis of H2O and CO2to produce sustainable fuels using solid oxide electrolysis cells (SOECs): advanced materials and technology. Chemical Society Reviews, 46(5), 1427-1463. doi:10.1039/c6cs00403b es_ES
dc.description.references Götz, M., Lefebvre, J., Mörs, F., McDaniel Koch, A., Graf, F., Bajohr, S., … Kolb, T. (2016). Renewable Power-to-Gas: A technological and economic review. Renewable Energy, 85, 1371-1390. doi:10.1016/j.renene.2015.07.066 es_ES
dc.description.references Woodhead publishing series in energy, Nr. 76, Membrane reactors for energy applications and basic chemical production, Edt. A. Basile, L. Di Paola, F.I. Hai, V. Piemonte, by Elsevier Ltd, ISBN 978-1-78242-223-5, 2015. es_ES
dc.description.references Morejudo, S. H., Zanón, R., Escolástico, S., Yuste-Tirados, I., Malerød-Fjeld, H., Vestre, P. K., … Kjølseth, C. (2016). Direct conversion of methane to aromatics in a catalytic co-ionic membrane reactor. Science, 353(6299), 563-566. doi:10.1126/science.aag0274 es_ES
dc.description.references Malerød-Fjeld, H., Clark, D., Yuste-Tirados, I., Zanón, R., Catalán-Martinez, D., Beeaff, D., … Kjølseth, C. (2017). Thermo-electrochemical production of compressed hydrogen from methane with near-zero energy loss. Nature Energy, 2(12), 923-931. doi:10.1038/s41560-017-0029-4 es_ES
dc.description.references J. Franz, Energetic and economic analysis of CO2 retention in coal gasification power plants by means of polymer and ceramic membranes (dissertation, German), Ruhr-University Bochum, Germany, Shaker Verlag, 2013. es_ES
dc.description.references Franz, J., & Scherer, V. (2011). Impact of ceramic membranes for CO2 separation on IGCC power plant performance. Energy Procedia, 4, 645-652. doi:10.1016/j.egypro.2011.01.100 es_ES
dc.description.references E. Forster, dissertation, Thermal stability of ceramic membranes and catalysts for H2-separation in CO-shift reactors, Energy and Environment Band, vol. 284, ISBN 978-3-95806-084-5, RUB 2015. es_ES
dc.description.references Escolástico, S., Stournari, V., Malzbender, J., Haas-Santo, K., Dittmeyer, R., & Serra, J. M. (2018). Chemical stability in H2S and creep characterization of the mixed protonic conductor Nd5.5WO11.25-δ. International Journal of Hydrogen Energy, 43(17), 8342-8354. doi:10.1016/j.ijhydene.2018.03.060 es_ES
dc.description.references Mortalò, C., Rebollo, E., Escolástico, S., Deambrosis, S., Haas-Santo, K., Rancan, M., … Fabrizio, M. (2018). Enhanced sulfur tolerance of BaCe0.65Zr0.20Y0.15O3-δ-Ce0.85Gd0.15O2-δ composite for hydrogen separation membranes. Journal of Membrane Science, 564, 123-132. doi:10.1016/j.memsci.2018.07.015 es_ES
dc.description.references Matsumoto, H., Shimura, T., Higuchi, T., Tanaka, H., Katahira, K., Otake, T., … Mizusaki, J. (2005). Protonic-Electronic Mixed Conduction and Hydrogen Permeation in BaCe[sub 0.9−x]Y[sub 0.1]Ru[sub x]O[sub 3−α]. Journal of The Electrochemical Society, 152(3), A488. doi:10.1149/1.1852442 es_ES
dc.description.references Cai, M., Liu, S., Efimov, K., Caro, J., Feldhoff, A., & Wang, H. (2009). Preparation and hydrogen permeation of BaCe0.95Nd0.05O3−δ membranes. Journal of Membrane Science, 343(1-2), 90-96. doi:10.1016/j.memsci.2009.07.011 es_ES
dc.description.references U. Balachandran, J. Guan, S.E. Dorris, A.C. Bose, G.J. Stiegel, in: Proceedings of the 5th ICIM, A-410, Nagoya, Japan, 1998. es_ES
dc.description.references Qi, X. (2000). Electrical conduction and hydrogen permeation through mixed proton–electron conducting strontium cerate membranes. Solid State Ionics, 130(1-2), 149-156. doi:10.1016/s0167-2738(00)00281-2 es_ES
dc.description.references Zhan, S., Zhu, X., Ji, B., Wang, W., Zhang, X., Wang, J., … Lin, L. (2009). Preparation and hydrogen permeation of SrCe0.95Y0.05O3−δ asymmetrical membranes. Journal of Membrane Science, 340(1-2), 241-248. doi:10.1016/j.memsci.2009.05.037 es_ES
dc.description.references Song, S. (2004). Hydrogen permeability of SrCe1−xMxO3−δ (x=0.05, M=Eu, Sm). Solid State Ionics, 167(1-2), 99-105. doi:10.1016/j.ssi.2003.12.010 es_ES
dc.description.references Wei, X., Kniep, J., & Lin, Y. S. (2009). Hydrogen permeation through terbium doped strontium cerate membranes enabled by presence of reducing gas in the downstream. Journal of Membrane Science, 345(1-2), 201-206. doi:10.1016/j.memsci.2009.08.041 es_ES
dc.description.references CHENG, S., GUPTA, V., & LIN, J. (2005). Synthesis and hydrogen permeation properties of asymmetric proton-conducting ceramic membranes. Solid State Ionics, 176(35-36), 2653-2662. doi:10.1016/j.ssi.2005.07.005 es_ES
dc.description.references Kniep, J., & Lin, Y. S. (2010). Effect of Zirconium Doping on Hydrogen Permeation through Strontium Cerate Membranes. Industrial & Engineering Chemistry Research, 49(6), 2768-2774. doi:10.1021/ie9015182 es_ES
dc.description.references LIANG, J., MAO, L., LI, L., & YUAN, W. (2010). Protonic and Electronic Conductivities and Hydrogen Permeation of SrCe0.95-xZrxTm0.05O3-δ(0≤x≤0.40) Membrane. Chinese Journal of Chemical Engineering, 18(3), 506-510. doi:10.1016/s1004-9541(10)60250-9 es_ES
dc.description.references Xing, W., Inge Dahl, P., Valland Roaas, L., Fontaine, M.-L., Larring, Y., Henriksen, P. P., & Bredesen, R. (2015). Hydrogen permeability of SrCe0.7Zr0.25Ln0.05O3− membranes (Ln=Tm and Yb). Journal of Membrane Science, 473, 327-332. doi:10.1016/j.memsci.2014.09.027 es_ES
dc.description.references Oh, T., Yoon, H., Li, J., & Wachsman, E. D. (2009). Hydrogen permeation through thin supported SrZr0.2Ce0.8−xEuxO3−δ membranes. Journal of Membrane Science, 345(1-2), 1-4. doi:10.1016/j.memsci.2009.08.031 es_ES
dc.description.references Hamakawa, S. (2002). Synthesis and hydrogen permeation properties of membranes based on dense SrCe0.95Yb0.05O3−α thin films. Solid State Ionics, 148(1-2), 71-81. doi:10.1016/s0167-2738(02)00047-4 es_ES
dc.description.references Escolástico, S., Ivanova, M., Solís, C., Roitsch, S., Meulenberg, W. A., & Serra, J. M. (2012). Improvement of transport properties and hydrogen permeation of chemically-stable proton-conducting oxides based on the system BaZr1-x-yYxMyO3-δ. RSC Advances, 2(11), 4932. doi:10.1039/c2ra20214j es_ES
dc.description.references H. Matsumoto, T. Shimura, T. Higuchi, T. Otake, Y. Sasaki, K. Yashiro, A. Kaimai, T. Kawada, J. Mizusaki, Mixed protonic-electronic conduction properties of SrZr0.9−xY0.1RuxO3−δ, Electrochemistry, 72(12), 861–864. es_ES
dc.description.references M.E. Ivanova, S. Escolático, M. Balaguer, J. Palisaitis, Y.J. Sohn, W.A. Meulenberg, O. Guillon, J. Mayer, J.M. Serra, Hydrogen separation through tailored dual phase membranes with nominal composition BaCe0.8Eu0.2O3−δ:Ce0.8Y0.2O2−δ at intermediate temperatures, Sci. Rep. 6 (2016) 34773–34787. es_ES
dc.description.references S. Elangovan, B.G. Nair, T.A. Small, Ceramic mixed protonic-electronic conducting membranes for hydrogen separation (2007), US 7,258,820 B2, 1997. es_ES
dc.description.references Rosensteel, W. A., Ricote, S., & Sullivan, N. P. (2016). Hydrogen permeation through dense BaCe 0.8 Y 0.2 O 3−δ – Ce 0.8 Y 0.2 O 2−δ composite-ceramic hydrogen separation membranes. International Journal of Hydrogen Energy, 41(4), 2598-2606. doi:10.1016/j.ijhydene.2015.11.053 es_ES
dc.description.references Rebollo, E., Mortalò, C., Escolástico, S., Boldrini, S., Barison, S., Serra, J. M., & Fabrizio, M. (2015). Exceptional hydrogen permeation of all-ceramic composite robust membranes based on BaCe0.65Zr0.20Y0.15O3−δ and Y- or Gd-doped ceria. Energy & Environmental Science, 8(12), 3675-3686. doi:10.1039/c5ee01793a es_ES
dc.description.references Montaleone, D., Mercadelli, E., Escolástico, S., Gondolini, A., Serra, J. M., & Sanson, A. (2018). All-ceramic asymmetric membranes with superior hydrogen permeation. Journal of Materials Chemistry A, 6(32), 15718-15727. doi:10.1039/c8ta04764b es_ES
dc.description.references Kim, H., Kim, B., Lee, J., Ahn, K., Kim, H.-R., Yoon, K. J., … Lee, J.-H. (2014). Microstructural adjustment of Ni–BaCe0.9Y0.1O3−δ cermet membrane for improved hydrogen permeation. Ceramics International, 40(3), 4117-4126. doi:10.1016/j.ceramint.2013.08.066 es_ES
dc.description.references (Balu) Balachandran, U., Lee, T. H., Park, C. Y., Emerson, J. E., Picciolo, J. J., & Dorris, S. E. (2014). Dense cermet membranes for hydrogen separation. Separation and Purification Technology, 121, 54-59. doi:10.1016/j.seppur.2013.10.001 es_ES
dc.description.references Shimura, T. (2001). Proton conduction in non-perovskite-type oxides at elevated temperatures. Solid State Ionics, 143(1), 117-123. doi:10.1016/s0167-2738(01)00839-6 es_ES
dc.description.references HAUGSRUD, R. (2007). Defects and transport properties in Ln6WO12 (Ln=La, Nd, Gd, Er). Solid State Ionics, 178(7-10), 555-560. doi:10.1016/j.ssi.2007.01.004 es_ES
dc.description.references Haugsrud, R., & Kjølseth, C. (2008). Effects of protons and acceptor substitution on the electrical conductivity of La6WO12. Journal of Physics and Chemistry of Solids, 69(7), 1758-1765. doi:10.1016/j.jpcs.2008.01.002 es_ES
dc.description.references Magrasó, A., Polfus, J. M., Frontera, C., Canales-Vázquez, J., Kalland, L.-E., Hervoches, C. H., … Haugsrud, R. (2012). Complete structural model for lanthanum tungstate: a chemically stable high temperature proton conductor by means of intrinsic defects. J. Mater. Chem., 22(5), 1762-1764. doi:10.1039/c2jm14981h es_ES
dc.description.references Seeger, J., Ivanova, M. E., Meulenberg, W. A., Sebold, D., Stöver, D., Scherb, T., … Serra, J. M. (2013). Synthesis and Characterization of Nonsubstituted and Substituted Proton-Conducting La6–xWO12–y. Inorganic Chemistry, 52(18), 10375-10386. doi:10.1021/ic401104m es_ES
dc.description.references Scherb, T., Kimber, S. A. J., Stephan, C., Henry, P. F., Schumacher, G., Escolástico, S., … Banhart, J. (2016). Nanoscale order in the frustrated mixed conductor La5.6WO12−δ. Journal of Applied Crystallography, 49(3), 997-1008. doi:10.1107/s1600576716006415 es_ES
dc.description.references Van Holt, D., Forster, E., Ivanova, M. E., Meulenberg, W. A., Müller, M., Baumann, S., & Vaßen, R. (2014). Ceramic materials for H2 transport membranes applicable for gas separation under coal-gasification-related conditions. Journal of the European Ceramic Society, 34(10), 2381-2389. doi:10.1016/j.jeurceramsoc.2014.03.001 es_ES
dc.description.references Forster, E., van Holt, D., Ivanova, M. E., Baumann, S., Meulenberg, W. A., & Müller, M. (2016). Stability of ceramic materials for H2 transport membranes in gasification environment under the influence of gas contaminants. Journal of the European Ceramic Society, 36(14), 3457-3464. doi:10.1016/j.jeurceramsoc.2016.05.021 es_ES
dc.description.references Medvedev, D., Lyagaeva, J., Plaksin, S., Demin, A., & Tsiakaras, P. (2015). Sulfur and carbon tolerance of BaCeO3–BaZrO3 proton-conducting materials. Journal of Power Sources, 273, 716-723. doi:10.1016/j.jpowsour.2014.09.116 es_ES
dc.description.references Yang, L., Wang, S., Blinn, K., Liu, M., Liu, Z., Cheng, Z., & Liu, M. (2009). Enhanced Sulfur and Coking Tolerance of a Mixed Ion Conductor for SOFCs: BaZr 0.1 Ce 0.7 Y 0.2– x Yb x O 3–δ. Science, 326(5949), 126-129. doi:10.1126/science.1174811 es_ES
dc.description.references Duan, C., Kee, R. J., Zhu, H., Karakaya, C., Chen, Y., Ricote, S., … O’Hayre, R. (2018). Highly durable, coking and sulfur tolerant, fuel-flexible protonic ceramic fuel cells. Nature, 557(7704), 217-222. doi:10.1038/s41586-018-0082-6 es_ES
dc.description.references Kreuer, K. D. (2003). Proton-Conducting Oxides. Annual Review of Materials Research, 33(1), 333-359. doi:10.1146/annurev.matsci.33.022802.091825 es_ES
dc.description.references Fantin, A., Scherb, T., Seeger, J., Schumacher, G., Gerhards, U., Ivanova, M. E., … Banhart, J. (2016). Crystal structure of Re-substituted lanthanum tungstate La5.4W1−y Re y O12–δ (0 ≤ y ≤ 0.2) studied by neutron diffraction. Journal of Applied Crystallography, 49(5), 1544-1560. doi:10.1107/s1600576716011523 es_ES
dc.description.references Fantin, A., Scherb, T., Seeger, J., Schumacher, G., Gerhards, U., Ivanova, M. E., … Banhart, J. (2017). Relation between composition and vacant oxygen sites in the mixed ionic-electronic conductors La5.4W1−MO12− (M= Mo, Re; 0 ≤y≤ 0.2) and their mother compound La6−WO12− (0.4 ≤x≤ 0.8). Solid State Ionics, 306, 104-111. doi:10.1016/j.ssi.2017.04.005 es_ES
dc.description.references J.M. Serra, S. Escolástico, M.E. Ivanova, W.A. Meulenberg, H.-P. Buchkremer, D. Stöver, US2013-0216938-A1, 2013. es_ES
dc.description.references Escolastico, S., Seeger, J., Roitsch, S., Ivanova, M., Meulenberg, W. A., & Serra, J. M. (2013). Enhanced H2Separation through Mixed Proton-Electron Conducting Membranes Based on La5.5W0.8M0.2O11.25−δ. ChemSusChem, 6(8), 1523-1532. doi:10.1002/cssc.201300091 es_ES
dc.description.references Gil, V., Gurauskis, J., Kjølseth, C., Wiik, K., & Einarsrud, M.-A. (2013). Hydrogen permeation in asymmetric La28 − xW4 + xO54 + 3x/2 membranes. International Journal of Hydrogen Energy, 38(7), 3087-3091. doi:10.1016/j.ijhydene.2012.12.105 es_ES
dc.description.references Palmqvist, L., Lindqvist, K., & Shaw, C. (2007). Porous Multilayer PZT Materials Made by Aqueous Tape Casting. Key Engineering Materials, 333, 215-218. doi:10.4028/www.scientific.net/kem.333.215 es_ES
dc.description.references Menzler, N. H., Malzbender, J., Schoderböck, P., Kauert, R., & Buchkremer, H. P. (2013). Sequential Tape Casting of Anode-Supported Solid Oxide Fuel Cells. Fuel Cells, 14(1), 96-106. doi:10.1002/fuce.201300153 es_ES
dc.description.references Schulze-Küppers, F., Baumann, S., Tietz, F., Bouwmeester, H. J. M., & Meulenberg, W. A. (2014). Towards the fabrication of La0.98−xSrxCo0.2Fe0.8O3−δ perovskite-type oxygen transport membranes. Journal of the European Ceramic Society, 34(15), 3741-3748. doi:10.1016/j.jeurceramsoc.2014.06.012 es_ES
dc.description.references Weirich, M., Gurauskis, J., Gil, V., Wiik, K., & Einarsrud, M.-A. (2012). Preparation of lanthanum tungstate membranes by tape casting technique. International Journal of Hydrogen Energy, 37(9), 8056-8061. doi:10.1016/j.ijhydene.2011.09.083 es_ES
dc.description.references Deibert, W., Schulze-Küppers, F., Forster, E., Ivanova, M. E., Müller, M., & Meulenberg, W. A. (2017). Stability and sintering of MgO as a substrate material for Lanthanum Tungstate membranes. Journal of the European Ceramic Society, 37(2), 671-677. doi:10.1016/j.jeurceramsoc.2016.09.033 es_ES
dc.description.references Escolástico, S., Vert, V. B., & Serra, J. M. (2009). Preparation and Characterization of Nanocrystalline Mixed Proton−Electronic Conducting Materials Based on the System Ln6WO12. Chemistry of Materials, 21(14), 3079-3089. doi:10.1021/cm900067k es_ES
dc.description.references Gil, V., Strøm, R. A., Groven, L. J., & Einarsrud, M.-A. (2012). La28−xW4+xO54+3x/2Powders Prepared by Spray Pyrolysis. Journal of the American Ceramic Society, 95(11), 3403-3407. doi:10.1111/j.1551-2916.2012.05377.x es_ES
dc.description.references Ivanova, M. E., Meulenberg, W. A., Palisaitis, J., Sebold, D., Solís, C., Ziegner, M., … Guillon, O. (2015). Functional properties of La0.99X0.01Nb0.99Al0.01O4−δ and La0.99X0.01Nb0.99Ti0.01O4−δ proton conductors where X is an alkaline earth cation. Journal of the European Ceramic Society, 35(4), 1239-1253. doi:10.1016/j.jeurceramsoc.2014.11.009 es_ES
dc.description.references Dittmeyer, R., Boeltken, T., Piermartini, P., Selinsek, M., Loewert, M., Dallmann, F., … Pfeifer, P. (2017). Micro and micro membrane reactors for advanced applications in chemical energy conversion. Current Opinion in Chemical Engineering, 17, 108-125. doi:10.1016/j.coche.2017.08.001 es_ES
dc.description.references Mauer, G., Vaßen, R., & Stöver, D. (2009). Thin and Dense Ceramic Coatings by Plasma Spraying at Very Low Pressure. Journal of Thermal Spray Technology, 19(1-2), 495-501. doi:10.1007/s11666-009-9416-0 es_ES
dc.description.references Bakan, E., & Vaßen, R. (2017). Ceramic Top Coats of Plasma-Sprayed Thermal Barrier Coatings: Materials, Processes, and Properties. Journal of Thermal Spray Technology, 26(6), 992-1010. doi:10.1007/s11666-017-0597-7 es_ES
dc.description.references Jarligo, M. O., Mauer, G., Bram, M., Baumann, S., & Vaßen, R. (2013). Plasma Spray Physical Vapor Deposition of La1−x Sr x Co y Fe1−y O3−δ Thin-Film Oxygen Transport Membrane on Porous Metallic Supports. Journal of Thermal Spray Technology, 23(1-2), 213-219. doi:10.1007/s11666-013-0004-y es_ES
dc.description.references Marcano, D., Mauer, G., Sohn, Y. J., Vaßen, R., Garcia-Fayos, J., & Serra, J. M. (2016). Controlling the stress state of La1−Sr Co Fe1−O3− oxygen transport membranes on porous metallic supports deposited by plasma spray–physical vapor process. Journal of Membrane Science, 503, 1-7. doi:10.1016/j.memsci.2015.12.029 es_ES
dc.description.references Marcano, D., Mauer, G., Vaßen, R., & Weber, A. (2017). Manufacturing of high performance solid oxide fuel cells (SOFCs) with atmospheric plasma spraying (APS) and plasma spray-physical vapor deposition (PS-PVD). Surface and Coatings Technology, 318, 170-177. doi:10.1016/j.surfcoat.2016.10.088 es_ES
dc.description.references D. Marcano, G. Mauer, Y.J. Sohn, A. Schwedt, M. Bram, M.E. Ivanova, R. Vaßen, Plasma spray-physical vapor deposition of single phase lanthanum tungstate for hydrogen gas separation membranes, t.b. submitted (2018). es_ES
dc.description.references Brunauer, S., Emmett, P. H., & Teller, E. (1938). Adsorption of Gases in Multimolecular Layers. Journal of the American Chemical Society, 60(2), 309-319. doi:10.1021/ja01269a023 es_ES
dc.description.references Ried, P., Lorenz, C., Brönstrup, A., Graule, T., Menzler, N. H., Sitte, W., & Holtappels, P. (2008). Processing of YSZ screen printing pastes and the characterization of the electrolyte layers for anode supported SOFC. Journal of the European Ceramic Society, 28(9), 1801-1808. doi:10.1016/j.jeurceramsoc.2007.11.018 es_ES
dc.description.references R. Mücke, Sintering of ZrO2-electrolytes in multilayered assemblies of SOFC, PhD Thesis, Ruhr-University, Bochum, 2007. es_ES
dc.description.references Amsif, M., Magrasó, A., Marrero-López, D., Ruiz-Morales, J. C., Canales-Vázquez, J., & Núñez, P. (2012). Mo-Substituted Lanthanum Tungstate La28–yW4+yO54+δ: A Competitive Mixed Electron–Proton Conductor for Gas Separation Membrane Applications. Chemistry of Materials, 24(20), 3868-3877. doi:10.1021/cm301723a es_ES
dc.description.references DANIELS, A. U., LOWRIE, R. C., GIBBY, R. L., & CUTLER, I. B. (1962). Observations on Normal Grain Growth of Magnesia and Calcia. Journal of the American Ceramic Society, 45(6), 282-285. doi:10.1111/j.1151-2916.1962.tb11145.x es_ES


Este ítem aparece en la(s) siguiente(s) colección(ones)

Mostrar el registro sencillo del ítem