Search Results - "anode"
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Suggested Topics within your search.
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1
Multicomponent reactions in organic synthesis /
Published 2015An electronic book accessible through the World Wide Web; click to view
Electronic eBook -
2
Multicomponent reactions in organic synthesis /
Published 2015An electronic book accessible through the World Wide Web; click to view
Electronic eBook -
3
Molten salts chemistry from lab to applications /
Published 2013Table of Contents: “…Modelling of molten salts -- Raman spectroscopy and pulsed neutron diffraction of molten salt mixtures containing rare earth trichlorides : trial approaches from fundamentals to pyrochemical reprocessing -- In situ spectroscopy in molten fluoride salts -- Thermodynamic calculations of molten salt reactor fuel systems -- Ionic transport in molten salts -- Salt bath thermal treating and nitriding -- Catalysis in molten ionic media -- The ability of molten carbonate for the gas cleaning of biomass gasification -- Inert anode development for high-temperature molten salts -- Boron-doped diamond electrode in molten chloride systems -- NF3 production from electrolysis in molten fluorides -- Corrosion in molten salts -- Plasma-induced discharge electrolysis for nanoparticles production -- Electrochemical formation of rare earth-nickel alloys -- Electrochemical synthesis of novel niobium and tantalum compounds in molten salts -- Preparation of carbonaceous materials in fused carbonates salts : applications to electrochemical storages devices -- Molten carbonates from fuel cells to new energy devices -- Synthesis and Li+ ion-exchange in molten salts of novel hollandite-type Ky(Mn1- xCox)O2zH2O nano-fiber for lithium battery electrodes -- Hybrid molten carbonate/solid oxide direct carbon fuel cells -- High temperature molten salts for solar power application -- The sodium metal halide (ZEBRA) battery : an example of inorganic molten salt electrolyte battery -- Hydrogen storage and transportation system through lithium hydride by using molten salt technology -- Nuclear energy based on thorium molten salt -- Molten salts for nuclear applications -- Lanthanides extraction processes in molten fluoride media -- Development of pyrochemical separation processes for recovery of actinides from spent nuclear fuel in molten LiCl-KCl.…”
An electronic book accessible through the World Wide Web; click to view
Electronic eBook -
4
Molten salts chemistry from lab to applications /
Published 2013Table of Contents: “…Modelling of molten salts -- Raman spectroscopy and pulsed neutron diffraction of molten salt mixtures containing rare earth trichlorides : trial approaches from fundamentals to pyrochemical reprocessing -- In situ spectroscopy in molten fluoride salts -- Thermodynamic calculations of molten salt reactor fuel systems -- Ionic transport in molten salts -- Salt bath thermal treating and nitriding -- Catalysis in molten ionic media -- The ability of molten carbonate for the gas cleaning of biomass gasification -- Inert anode development for high-temperature molten salts -- Boron-doped diamond electrode in molten chloride systems -- NF3 production from electrolysis in molten fluorides -- Corrosion in molten salts -- Plasma-induced discharge electrolysis for nanoparticles production -- Electrochemical formation of rare earth-nickel alloys -- Electrochemical synthesis of novel niobium and tantalum compounds in molten salts -- Preparation of carbonaceous materials in fused carbonates salts : applications to electrochemical storages devices -- Molten carbonates from fuel cells to new energy devices -- Synthesis and Li+ ion-exchange in molten salts of novel hollandite-type Ky(Mn1- xCox)O2zH2O nano-fiber for lithium battery electrodes -- Hybrid molten carbonate/solid oxide direct carbon fuel cells -- High temperature molten salts for solar power application -- The sodium metal halide (ZEBRA) battery : an example of inorganic molten salt electrolyte battery -- Hydrogen storage and transportation system through lithium hydride by using molten salt technology -- Nuclear energy based on thorium molten salt -- Molten salts for nuclear applications -- Lanthanides extraction processes in molten fluoride media -- Development of pyrochemical separation processes for recovery of actinides from spent nuclear fuel in molten LiCl-KCl.…”
An electronic book accessible through the World Wide Web; click to view
Electronic eBook -
5
PEM fuel cells thermal and water management fundamentals /
Published 2013Table of Contents: “…Thermal transport and management -- 8.1 Heat transfer overview -- 8.1.1 Heat transfer and its importance -- 8.1.2 Heat transfer modes -- 8.1.2.1 Heat conduction -- 8.1.2.2 Convective heat transfer -- 8.1.2.3 Heat radiation -- 8.1.3 Heat transfer in porous media -- 8.2 Heating mechanisms -- 8.2.1 The entropic heat -- 8.2.2 Irreversibility of the electrochemical reactions -- 8.2.3 The Joules heat -- 8.3 Steady-state heat transfer -- 8.3.1 One-dimensional (1D) heat transfer analysis -- 8.3.2 Two-dimensional (2D) heat transfer analysis -- 8.3.3 Numerical analysis -- 8.3.3.1 Macroscopic model prediction -- 8.3.3.2 Pore-level heat transfer -- 8.4 Transient phenomena -- 8.4.1 General transient operation -- 8.4.2 Transient subfreezing operation -- 8.4.2.1 Temperature evolution and voltage loss -- 8.4.2.2 Activation voltage loss -- 8.4.2.3 Ohmic voltage loss -- 8.5 Experimental measurement of thermal conductivity -- 8.6 Cooling methods -- 8.6.1 Heat spreaders cooling -- 8.6.2 Cooling by air or liquid flow -- 8.6.3 Phase-change-based cooling -- 8.7 Example: a thermal system of automotive fuel cells -- 8.7.1 A lumped-system model of a PEM fuel cell -- 8.7.2 Bypass valve -- 8.7.3 Radiator -- 8.7.4 Transport delay -- 8.7.5 Fluid mixer -- 8.7.6 Cathode intercooler -- 8.7.7 Anode heat exchanger -- 8.8 Chapter summary --…”
An electronic book accessible through the World Wide Web; click to view
Electronic eBook -
6
PEM fuel cells thermal and water management fundamentals /
Published 2013Table of Contents: “…Thermal transport and management -- 8.1 Heat transfer overview -- 8.1.1 Heat transfer and its importance -- 8.1.2 Heat transfer modes -- 8.1.2.1 Heat conduction -- 8.1.2.2 Convective heat transfer -- 8.1.2.3 Heat radiation -- 8.1.3 Heat transfer in porous media -- 8.2 Heating mechanisms -- 8.2.1 The entropic heat -- 8.2.2 Irreversibility of the electrochemical reactions -- 8.2.3 The Joules heat -- 8.3 Steady-state heat transfer -- 8.3.1 One-dimensional (1D) heat transfer analysis -- 8.3.2 Two-dimensional (2D) heat transfer analysis -- 8.3.3 Numerical analysis -- 8.3.3.1 Macroscopic model prediction -- 8.3.3.2 Pore-level heat transfer -- 8.4 Transient phenomena -- 8.4.1 General transient operation -- 8.4.2 Transient subfreezing operation -- 8.4.2.1 Temperature evolution and voltage loss -- 8.4.2.2 Activation voltage loss -- 8.4.2.3 Ohmic voltage loss -- 8.5 Experimental measurement of thermal conductivity -- 8.6 Cooling methods -- 8.6.1 Heat spreaders cooling -- 8.6.2 Cooling by air or liquid flow -- 8.6.3 Phase-change-based cooling -- 8.7 Example: a thermal system of automotive fuel cells -- 8.7.1 A lumped-system model of a PEM fuel cell -- 8.7.2 Bypass valve -- 8.7.3 Radiator -- 8.7.4 Transport delay -- 8.7.5 Fluid mixer -- 8.7.6 Cathode intercooler -- 8.7.7 Anode heat exchanger -- 8.8 Chapter summary --…”
An electronic book accessible through the World Wide Web; click to view
Electronic eBook