Proton Exchange Membrane Fuel Cells (PEMFCs)
Material type:
ArticleLanguage: English Publication details: Basel MDPI - Multidisciplinary Digital Publishing Institute 2022Description: 1 electronic resource (214 p.)ISBN: - books978-3-0365-1543-4
- 9783036515441
- 9783036515434
- Technology: general issues
- Chemical engineering
- PEM fuel cell
- membrane electrode assembly (MEA)
- response surface method
- computational fuel cell dynamics
- fuel impurities
- ISO concentration
- ultralow-loaded anode catalyst layer
- platinum electrode
- shut-down and start-up process
- proton exchange membrane fuel cell
- graphene thin film
- current collector
- module
- proton exchange membrane fuel cells
- durability
- contamination
- cathode
- catalyst loading
- performance
- recovery
- nitrogen dioxide
- subzero cold-starts
- automotive
- isothermal water fill tests
- PEMFCs
- asymmetric &
- symmetric GDM
- Freudenberg
- SGL 29BC
- dead-ended anode (DEA) mode
- cathode catalyst layer
- I/C ratio
- diffusion limitation
- conductivity limitation
- composite membranes
- electrolyte
- PEM
- fuel cells
- electrolysers
- oxygen reduction
- oxygen evolution
- PEM water electorolyzer
- porous structure
- carbon-free
- catalyst layer
- polymer electrolyte fuel cell
- oxygen transport resistance
- oxygen reduction reaction kinetics
- platinum ionomer interface
- ionomer thin film
| Item type | Home library | Collection | Call number | Materials specified | Status | Date due | Barcode | |
|---|---|---|---|---|---|---|---|---|
Electronic-Books
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OPJGU Sonepat- Campus | E-Books Open Access | Available |
Open Access star Unrestricted online access
The proton exchange membrane fuel cell is an electrochemical energy conversion device, which transforms a fuel such as hydrogen and an oxidant such as oxygen in ambient air into electricity with heat and water byproducts. The device is more efficient than an internal combustion engine because reactants are directly converted into energy through a one-step electrochemical reaction. Fuel cells combined with water electrolyzers, which electrochemically split water into hydrogen and oxygen using renewable energy sources such as solar, mitigate global warming concerns with reduced carbon dioxide emissions. This collection of papers covers recent advancements in fuel cell technology aimed at reducing cost, improving performance, and extending durability, which are perceived as crucial for a successful commercialization. Almost all key materials, as well as their integration into a cell, are discussed: the bus plates that collect the electrical current, the gas diffusion medium that distributes the reactants over catalysts promoting faster reactions, and the membrane separating oxygen and hydrogen gases and closing the electrical circuit by transporting protons. Fuel cell operation below the freezing point of water and with impure reactant streams, which impacts durability, is also discussed.
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