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Polyelectrolytes. --- Polymer electrolytes --- Polymeric electrolytes --- Electrolytes --- Polymers

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For full market implementation of PEM fuel cells to become a reality, two main limiting technical issues must be overcome- cost and durability. This cutting-edge volume directly addresses the state-of-the-art advances in durability within every fuel cell stack component. [...] chapters on durability in the individual fuel cell components -- membranes, electrodes, diffusion media, and bipolar plates -- highlight specific degradation modes and mitigation strategies. The book also includes chapters which synthesize the component-related failure modes to examine experimental diagnostics, computational modeling, and laboratory protocol"--Back cover.

Fuel cells. --- Fuel cells --- Polyelectrolytes. --- Reliability.

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Biopolymer Electrolytes: Fundamentals and Applications in Energy Storage provides the core fundamentals and applications for polyelectrolytes and their properties with a focus on biopolymer electrolytes. Increasing global energy and environmental challenges demand clean and sustainable energy sources to support the modern society. One of the feasible technologies is to use green energy and green materials in devices. Biopolymer electrolytes are one such green material and, hence, have enormous application potential in devices such as electrochemical cells and fuel cells. Features a stable of case studies throughout the book that underscore key concepts and applications Provides the core fundamentals and applications for polyelectrolytes and their properties Weaves the subject of biopolymer electrolytes across a broad range of disciplines, including chemistry, chemical engineering, materials science, environmental science, and pharmaceutical science.--

Electrochemistry --- Polyelectrolytes. --- Biopolymers. --- Electrolytes. --- Electrochemistry. --- Chemistry, Physical and theoretical --- Bioactive polymers --- Biological polymers --- Natural polymers --- Naturally occurring polymers --- Biomolecules --- Polymers --- Polymer electrolytes --- Polymeric electrolytes --- Electrolytes

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Roland G. Winkler and Andrey G. Cherstvy Strong and Weak Polyelectrolyte Adsorption onto Oppositely Charged Curved Surfaces Nikolai I. Lebovka Aggregation of Charged Colloidal Particles Cornelia Cramer and Monika Schönhoff Ion Conduction in Solid Polyelectrolyte Complex Materials Saskia Lindhoud and Martien A. Cohen Stuart Relaxation phenomena during polyelectrolyte complex formation Dmitry V. Pergushov, Alexey A. Zezin, Alexander B. Zezin, and Axel H.E. Müller Advanced Functional Structures Based on Interpolyelectrolyte Complexes.

Chemistry. --- Polymers. --- Biochemistry. --- Polymer Sciences. --- Electrochemistry. --- Biochemistry, general. --- Chemistry --- Physical Sciences & Mathematics --- Organic Chemistry --- Biological chemistry --- Chemical composition of organisms --- Organisms --- Physiological chemistry --- Polymere --- Polymeride --- Polymers and polymerization --- Composition --- Biology --- Medical sciences --- Macromolecules --- Physical sciences --- Chemistry, Physical and theoretical --- Polyelectrolytes. --- Polymer electrolytes --- Polymeric electrolytes --- Electrolytes --- Polymers --- Polymers  .

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This brief is the result of the research the author has performed in recent years covering electrical fluctuations in numerous systems, including molecular electrical fluctuations, ionic fluctuations, ionic dielectric relaxation, spherical and cylindrical polyelectrolytes, ionic polarizability in polyelectrolytes, pH fluctuation in vesicles and electrical fluctuations in proteins. The importance of estimating electrical fluctuations resides in its richness of information and omnipresence in biological systems. In order to understand how these systems work it is vital to know the magnitude of their electrical fluctuations. Electromagnetic fluctuations are the origin of London (Van der Waals) forces between molecules, and Lifshitz forces between macro objects. Protonic fluctuations are the origin of Kirkwood and Shumaker forces between molecules and pH fluctuations. Furthermore, protonic fluctuations could be the cause of the dielectric increment of proteins in solution. Local electrical fluctuations can influence chemical reactions and so on. This book addresses the interplay of these pervasive phenomena. .

Nanoscale science. --- Biological physics. --- Nanoscale Science and Technology. --- Chemistry. --- Electrochemistry. --- Nanoscience. --- Nanostructures. --- Biophysics. --- Nanotechnology. --- Biophysics and Biological Physics. --- Polyelectrolytes. --- Polymer electrolytes --- Polymeric electrolytes --- Electrolytes --- Polymers --- Biological and Medical Physics, Biophysics. --- Molecular technology --- Nanoscale technology --- High technology --- Physical sciences --- Nanoscience --- Physics --- Nano science --- Nanoscale science --- Nanosciences --- Science --- Biological physics --- Biology --- Medical sciences --- Chemistry, Physical and theoretical --- Nanophysics.