Search results for "Fuel Cells"

showing 10 items of 83 documents

Interdependence of Oxygenation and Hydration in Mixed-Conducting (Ba,Sr)FeO3-δPerovskites Studied by Density Functional Theory

2020

Financial support by the German–Israeli Foundation for Scientific Research and Development (grant I-1342-302.5/2016) and the Latvian Council of Science (grant lzp-2018/1-0147 (D.G., E.A.K.)) is gratefully acknowledged. The authors further thank Guntars Zvejnieks for help with CRYSTAL code calculations.

Materials science02 engineering and technologyElectronic structure010402 general chemistry021001 nanoscience & nanotechnology7. Clean energy01 natural sciencesCathode0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic Materialslaw.inventionGeneral EnergyChemical engineering13. Climate actionlawvisual_artvisual_art.visual_art_medium:NATURAL SCIENCES:Physics [Research Subject Categories]Fuel cellsDensity functional theoryCeramicPhysical and Theoretical Chemistry0210 nano-technology
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Interface Solid-State Reactions in La0.8Sr0.2MnO3/Ce0.8Sm0.2O2 and La0.8Sr0.2MnO3/BaCe0.9Y0.1O3 Disclosed by X-ray Microspectroscopy

2019

The stability of the electrode/electrolyte interface is a critical issue in solid-oxide cells working at high temperatures, affecting their durability. In this paper, we investigate the solid-state chemical mechanisms that occur at the interface between two electrolytes (Ce0.8Sm0.2O2, SDC, and BaCe0.9Y0.1O3, BCY) and a cathode material (La0.8Sr0.2MnO3, LSM) after prolonged thermal treatments. Following our previous work on the subject, we used X-ray microspectroscopy, a technique that probes the interface with submicrometric resolution combining microanalytical information with the chemical and structural information coming from space-resolved X-ray absorption spectroscopy. In LSM/BCY, the …

Materials scienceAbsorption spectroscopyXASXRFAnalytical chemistryEnergy Engineering and Power Technologychemistry.chemical_elementManganeseElectrolytefuel cellselectrolytecompatibilitySDCfuel cellchemistry.chemical_compoundThermalMaterials ChemistryElectrochemistryID21Chemical Engineering (miscellaneous)materials compatibilityESRFx-ray microspectroscopySOFCElectrical and Electronic Engineeringx-ray fluorescenceLanthanum strontium manganiteX-rayBCYelectrodeXANESceriaChemical statelanthanum strontium manganitechemistryElectrodeinterdiffusionbarium cerate
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Strontium and iron-doped barium cobaltite prepared by solution combustion synthesis: exploring a mixed-fuel approach for tailored intermediate temper…

2013

Ba0.5Sr0.5Co0.8Fe0.2O3-? (BSCF) powders were prepared by solution combustion synthesis using single and double fuels. The effect of the fuel mixture on the main properties of this well-known solid oxide fuel cell cathode material with high oxygen ion and electronic conduction was investigated in detail. Results showed that the fuel mixture significantly affected the area-specific resistance of the BSCF cathode materials, by controlling the oxygen deficiency and stabilizing the Co2+ oxidation state. It was demonstrated that high fuel-to-metal cations molar ratios and high reducing power of the combustion fuel mixture are mainly responsible for the decreasing of the area-specific resistance o…

Materials scienceCathode materialsInorganic chemistrychemistry.chemical_elementBSCFCombustionlaw.inventionchemistry.chemical_compoundOxidation statelawPhase (matter)Materials ChemistryChatode materialIntermediate temperature solid oxide fuel cellsStrontiumRenewable Energy Sustainability and the EnvironmentPerovskite-type materialsBariumPerovskite-type compoundsCombustion fuel mixtureCathodeElectronic Optical and Magnetic MaterialsCobaltiteFuel TechnologychemistrySolution combustion synthesisSolid oxide fuel cellSettore CHIM/07 - Fondamenti Chimici Delle TecnologieMaterials for Renewable and Sustainable Energy
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First principles calculations of oxygen reduction reaction at fuel cell cathodes

2020

This study was partly supported by M-ERA-NET project SunToChem (EK, YM). The computer resources were provided by Stuttgart Super-computing Center (Project DEFTD 12939). Authors thank E. Heifets, M. M. Kuklja, M. Arrigoni, D. Morgan, R. Evarestov, and D. Gryaznov for fruitful discussions.

Materials scienceCathode materialsKineticsAb initioOxideAnalytical chemistry02 engineering and technology010402 general chemistry01 natural sciencesAnalytical Chemistrylaw.inventionOxygen reduction Reaction (ORR)chemistry.chemical_compoundSurface arealawVacancy defectElectrochemistry:NATURAL SCIENCES:Physics [Research Subject Categories]PerovskitesFuel cellsPerovskite (structure)Rate determining step021001 nanoscience & nanotechnologyRate-determining stepCathode0104 chemical sciencesPolar surfaceschemistry0210 nano-technologyFirst principles calculations
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Micro bial fuel cell with Ni-Co cathode

2017

Materials scienceChemical engineeringlawFuel cells02 engineering and technologyGeneral Medicine010501 environmental sciences021001 nanoscience & nanotechnology0210 nano-technology01 natural sciencesCathode0105 earth and related environmental scienceslaw.inventionRUDY I METALE NIEŻELAZNE
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Wood and Black Liquor-Based N-Doped Activated Carbon for Energy Application

2021

The research was funded by the Latvian Council of Science project “Nanostructured Nitrogenated Carbon Materials as Promoters in Energy Harvesting and Storage Technologies”, project No LZP-2018/1-0194, “New biomass origin materials hybrid carbon composites for energy storage” project No LZP-2020/2-0019 and postdoc project “Nitrogen and phosphorus-containing biomass based activated carbons for fuel cells and supercapacitors” project No 1.1.1.2/VIAA/4/20/596.

Materials scienceGeography Planning and Developmentchemistry.chemical_elementBiomassLi-ion batteriesTJ807-83002 engineering and technologyfuel cellsManagement Monitoring Policy and LawPorous structure010402 general chemistryTD194-1957. Clean energy01 natural sciencesRenewable energy sourcesCatalysismedicineGE1-350BiomassCharFuel cellsActivated carbonsSupercapacitorporous structurebiomassactivated carbonsEnvironmental effects of industries and plantsRenewable Energy Sustainability and the EnvironmentNanoporous021001 nanoscience & nanotechnology0104 chemical sciencesEnvironmental sciencesChemical engineeringchemistry13. Climate action:NATURAL SCIENCES [Research Subject Categories]0210 nano-technologyCarbonBlack liquorActivated carbonmedicine.drugSustainability
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Nanoscale membrane electrode assemblies based on porous anodic alumina for hydrogen–oxygen fuel cell

2007

In this paper, we demonstrate that nanoscale membrane electrode assemblies, functioning in a H 2/O 2 fuel cell, can be fabricated by impregnation of anodic alumina porous membranes with Nafion® and phosphotungstic acid. Porous anodic alumina is potentially a promising material for thin-film micro power sources because of its ability to be manipulated in micro-machining operations. Alumina membranes (Whatman, 50 μm thick, and pore diameters of 200 nm) impregnated with the proton conductor were characterized by means of scanning electron microscopy, X-ray diffraction, and thermal analysis. The electrochemical characterization of the membrane electrode assemblies was carried out by recording t…

Materials scienceHydrogenAnalytical chemistrychemistry.chemical_elementFuel cells Protons Intermediate temperatureCondensed Matter PhysicsElectrochemistryAnodechemistry.chemical_compoundMembranechemistryChemical engineeringElectrodeElectrochemistryGeneral Materials ScienceComposite proton conductors Hydrogen-oxygen fuel cell Porous anodic aluminaPhosphotungstic acidElectrical and Electronic EngineeringPolarization (electrochemistry)Proton conductorJournal of Solid State Electrochemistry
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Oxide-based nanomaterials for fuel cell catalysis:the interplay between supported single Pt atoms and particles

2017

The concept of single atom catalysis offers maximum noble metal efficiency for the development of low-cost catalytic materials. Among possible applications are catalytic materials for proton exchange membrane fuel cells. In the present review, recent efforts towards the fabrication of single atom catalysts on nanostructured ceria and their reactivity are discussed in the prospect of their employment as anode catalysts. The remarkable performance and the durability of the ceria-based anode catalysts with ultra-low Pt loading result from the interplay between two states associated with supported atomically dispersed Pt and sub-nanometer Pt particles. The occurrence of these two states is a co…

Materials sciencePHOTOELECTRON-SPECTROSCOPYReducing agentCatalitzadorsOxideProton exchange membrane fuel cellNanotechnology02 engineering and technologyengineering.material010402 general chemistry01 natural sciencesRedoxPALLADIUM NANOPARTICLESCatalysisNanomaterialsCatalysischemistry.chemical_compoundAdsorptionPiles de combustibleD-METAL ATOMSFuel cellsCatalystsCEO2(111) SURFACECO OXIDATIONIN-SITUNanostructured materialsSILICON SUBSTRATE021001 nanoscience & nanotechnology0104 chemical scienceschemistryChemical engineeringGRAPHITE FOILengineeringTHIN-FILM CATALYSTSNoble metalMaterials nanoestructuratsCERIA-BASED OXIDE0210 nano-technology
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Recent Progress in the Development of Composite Membranes Based on Polybenzimidazole for High Temperature Proton Exchange Membrane (PEM) Fuel Cell Ap…

2020

[EN] The rapid increasing of the population in combination with the emergence of new energy-consuming technologies has risen worldwide total energy consumption towards unprecedent values. Furthermore, fossil fuel reserves are running out very quickly and the polluting greenhouse gases emitted during their utilization need to be reduced. In this scenario, a few alternative energy sources have been proposed and, among these, proton exchange membrane (PEM) fuel cells are promising. Recently, polybenzimidazole-based polymers, featuring high chemical and thermal stability, in combination with fillers that can regulate the proton mobility, have attracted tremendous attention for their roles as PE…

Materials sciencePolymers and PlasticspolymerPopulationCarbon nanotubesMetal organic frameworksProton exchange membrane fuel cellNanotechnologyReviewfuel cellsProton exchange membranelcsh:QD241-441lcsh:Organic chemistryFast ion conductorFuel cellsPolymereducationGraphene oxidechemistry.chemical_classificationConductivityeducation.field_of_studybusiness.industryFossil fuelComposite membranesGeneral ChemistryPolymerPolybenzimidazoleIonic liquidspolybenzimidazolechemistryMAQUINAS Y MOTORES TERMICOSAlternative energyFuel cellsComposite membraneconductivitybusinesscomposite membranesproton exchange membranePolymers
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Proton conductivity through polybenzimidazole composite membranes containing silica nanofiber mats

2019

The quest for sustainable and more efficient energy-converting devices has been the focus of researchers&prime

Materials sciencePolymers and PlasticspolymerProton exchange membrane fuel cellfuel cellssilici compostosArticlelcsh:QD241-441chemistry.chemical_compoundlcsh:Organic chemistrynanofibersThermal stabilitysolucions polimèriquesComputingMilieux_MISCELLANEOUSelectrospinningchemistry.chemical_classificationGeneral ChemistryPolymerSilaneElectrospinningDielectric spectroscopypolybenzimidazoleMembraneelectrochemical impedance spectroscopychemistryChemical engineeringsilicaNanofiberproton conductivityconductivitat elèctricaproton exchange membrane
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