Search results for " fuel cell."

showing 10 items of 166 documents

Surface Self-Diffusion and Mean Displacement of Hydrogen on Graphite and a PEM Fuel Cell Catalyst Support

2009

International audience; Quasielastic neutron scattering (QENS) measurements together with equilibrium molecular dynamic (EMD) simulations have been performed to investigate the surface interaction between hydrogen molecules and a carbon material commonly used in polymer electrolyte membrane fuel cells (PEMFC), called XC-72. Half a monolayer of molecular hydrogen was adsorbed on to the carbon material at 2 K. QENS spectra were recorded at the time-of-flight spectrometer IN5 at 40, 45, 50, 60, 70, 80, and 90 K. Simultaneously the pressure was measured as a function of time to monitor the equilibrium surface coverage at each temperature. By using the Chudley and Elliott model for jump diffusio…

Self-diffusionHydrogenCatalyst supportDiffusionAnalytical chemistryProton exchange membrane fuel cellchemistry.chemical_element02 engineering and technologyElectrolyte010402 general chemistry01 natural sciences7. Clean energy[PHYS.PHYS.PHYS-CHEM-PH] Physics [physics]/Physics [physics]/Chemical Physics [physics.chem-ph]GraphitePhysical and Theoretical ChemistryComputingMilieux_MISCELLANEOUSChemistry021001 nanoscience & nanotechnology0104 chemical sciencesSurfaces Coatings and FilmsElectronic Optical and Magnetic Materials[CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistry[CHIM.THEO] Chemical Sciences/Theoretical and/or physical chemistry[ PHYS.PHYS.PHYS-CHEM-PH ] Physics [physics]/Physics [physics]/Chemical Physics [physics.chem-ph]General EnergyQuasielastic neutron scattering[ CHIM.THEO ] Chemical Sciences/Theoretical and/or physical chemistry[PHYS.PHYS.PHYS-CHEM-PH]Physics [physics]/Physics [physics]/Chemical Physics [physics.chem-ph]0210 nano-technology
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Life cycle assessment of solid oxide fuel cells and polymer electrolyte membrane fuel cells: A review

2017

Fuel cells (FCs) are among the key technologies that Europe will have to rely on in order to comply with the most recent environmental targets inspired by decarbonization and circular economy. The assessment of the real advantages of using FCs for producing energy must include a reliable analysis of the energy and environmental impacts during the life cycle of these systems, including the raw materials supply, production, use, and disposal. In this context, the life cycle assessment (LCA) is a well-established methodology for assessing the eco-profile of products and services and for identifying the components and the life cycle steps having the largest contribution to energy and environmen…

Settore ING-IND/11 - Fisica Tecnica AmbientalePolymer Electrolyte Fuel CellReviewLife Cycle AssessmentPolymer Electrolyte MembraneSolid Oxide Fuel Cell
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Analysis of Load Match in Nearly Zero Energy Buildings

2018

The concept of load matching refers to the degree of agreement or disagreement of the on-site generation with the building load profiles: it can be increased and optimised with modifications on both the energy demand and generation. In this context, the paper presents the load match analysis of a case study: a modular housing construction (it has an area of 45 m 2 and S/V ratio equal to 2.75 m −1 ) built in Messina (Italy). Moreover, in order to optimize the design of the next test module to be built, a parametric analysis was performed considering different scenarios on the generation side, to explore the effectiveness of the solutions sets used in current design and plan different solutio…

Settore ING-IND/11 - Fisica Tecnica AmbientaleZero-energy buildingCover (telecommunications)Degree (graph theory)Computer sciencebusiness.industryLoad Matching nearly Zero Energy Buildings Energy storage renewable energy use in buildings fuel cellsContext (language use)Atmospheric modelModular designBase (topology)Automotive engineeringEnergy storagebusiness2018 IEEE 4th International Forum on Research and Technology for Society and Industry (RTSI)
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Heteropolyacids - Chitosan Membranes for H2/O2 Low Temperature Fuel Cells

2016

Proton exchange membrane fuel cells (PEMFCs) have received much attention in recent years because of their high power density, efficiency and zero-environmental pollution. As one of the key components in fuel cells, the proton exchange membrane is expected to have high proton conductivity and good electrochemical stability. In the attempt to promote PEMCFs commercialization, high cost of fuel cell systems and short lifecycle are the two main issues that need to be addressed, thus large research effort has been devoted in developing new polymer electrolytes that can replace the usually employed proton conductors, e.g. Nafion®, with other membranes of comparable performances but lower cost.A…

Settore ING-IND/23 - Chimica Fisica ApplicataChemical engineeringChitosan membraneChemistryHeteropolyacids Chitosan Membranes H2/O2 Low Temperature Fuel CellsFuel cellsECS Transactions
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Chitosan-heteropolyacid complex as high performance membranes for low temperature H2-O2 fuel cell

2014

Settore ING-IND/23 - Chimica Fisica ApplicataChitosan-heteropolyacid complex high performance membranes low temperature H2-O2 fuel cell PEMFC Electrochemical Impedance Spectroscopy XRD SEM EDX
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Heteropolyacids - Chitosan Membranes for H2/O2 Low Temperature Fuel Cells

2016

Proton exchange membrane fuel cells (PEMFCs) have received much attention in recent years because of their high power density, efficiency and zero-environmental pollution. As one of the key components in fuel cells, the proton exchange membrane is expected to have high proton conductivity and good electrochemical stability. In the attempt to promote PEMCFs commercialization, high cost of fuel cell systems and short lifecycle are the two main issues that need to be addressed, thus large research effort has been devoted in developing new polymer electrolytes that can replace the usually employed proton conductors, e.g. Nafion®, with other membranes of comparable performances but lower cost. A…

Settore ING-IND/23 - Chimica Fisica ApplicataHeteropolyacids Chitosan Membranes H2/O2 Low Temperature Fuel Cells
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Hybrid organic-inorganic membranes for low temperature H2-O2 fuel cell

2014

Settore ING-IND/23 - Chimica Fisica ApplicataHybrid organic-inorganic membranes low temperature H2-O2 fuel cell electrochemical impedance spectroscopy polarization curves XRD SEM EDX
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Phosphomolybdic Acid and Mixed Phosphotungstic/Phosphomolybdic Acid Chitosan Membranes for H2/O2 Fuel Cells

2016

Proton exchange membrane fuel cells (PEMFCs) have received much attention in recent years because of their high power density, efficiency and zero-environmental pollution. As one of the key components in fuel cells, the proton exchange membrane is expected to have high proton conductivity and good electrochemical stability. In the attempt to promote PEMCFs commercialization, high cost of fuel cell systems and short lifecycle are the two main issues that need to be addressed, thus large research effort has been devoted in developing new polymer electrolytes that can replace the usually employed proton conductors, e.g. Nafion®, with other membranes of comparable performances but lower cost. A…

Settore ING-IND/23 - Chimica Fisica ApplicataPhosphomolybdic Acid Phosphotungstic/Phosphomolybdic Acid Chitosan Membranes H2/O2 Fuel Cells
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Influence of heteropolyacid in enhancing proton conductivity of chitosan membranes for H2/O2 Fuel Cells

2016

To promote Proton Exchange Membrane Fuel Cells (PEMFCs) commercialization, large research effort has been devoted in developing new polymer electrolytes that can replace the usually employed proton conductors, e.g. Nafion®, with other membranes of comparable performances but lower cost. Chitosan (CS)-based membrane electrolyte is currently studied as alternative candidate for PEMFC application. Several works have shown that Heteropolyacids (HPAs) can be used to prepare Chitosan polyelectrolytes (PECs) to be employed as proton exchange membrane in low temperature fuel cell. In previous works [1-3] we have shown that CS/PTA membranes, prepared using alumina porous medium for the slow release …

Settore ING-IND/23 - Chimica Fisica Applicataheteropolyacid proton conductivity chitosan membranes H2/O2 Fuel Cells
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The influence of sludge retention time on mixed culture microbial fuel cell start-ups

2017

Abstract In this work, the start-ups of air-cathode microbial fuel cells (MFCs) seeds with conventional activated sludge cultivated at different solid retention times (SRTs) are compared. A clear influence of the SRT of the inoculum was observed, corresponding to an SRT of 10 days to the higher current density exerted, about 0.2 A m −2 . This observation points out that, in this type of electrochemical device, it is recommended to use high SRT seeds. The work also points out that in order to promote an efficient start-up, it is not only necessary to use high SRT seeds, but also to feed a high COD concentration. When feeding 10,000 ppm COD and keeping SRT of 10 d differences of current densi…

Settore ING-IND/26 - Teoria Dello Sviluppo Dei Processi ChimiciEnvironmental EngineeringMicrobial fuel cellMicrobial fuel cellAir-cathodeBiomedical EngineeringBioengineering02 engineering and technology010501 environmental sciencesSolid retention time Microbial fuel cell Air-cathode Acetate01 natural sciencesMixed culture0105 earth and related environmental sciencesSolid retention timChemistryAir cathodeAcetateEnvironmental engineeringSettore ING-IND/27 - Chimica Industriale E Tecnologica021001 nanoscience & nanotechnologyPulp and paper industryStart upSolid retention time Microbial fuel cell Air-cathode AcetateActivated sludge0210 nano-technologyRetention timehuman activitiesBiotechnology
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