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Molecular theory of electric double layers /

The electrical double layer describes charge and potential distributions that form at the interface between electrolyte solutions and the surface of an object, and they play a fundamental role in chemical and electrochemical behaviour. Colloid science, electrochemistry, material science, and biology...

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Detalles Bibliográficos
Clasificación:Libro Electrónico
Autores principales: Petsev, D. N. (Dimiter Nikolov), 1962- (Autor), Swol, Frank van (Autor), Frink, Laura J. D. (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2021]
Colección:IOP (Series). Release 21.
IOP ebooks. 2021 collection.
Temas:
Acceso en línea:Texto completo

MARC

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100 1 |a Petsev, D. N.  |q (Dimiter Nikolov),  |d 1962-  |e author. 
245 1 0 |a Molecular theory of electric double layers /  |c Dimiter N. Petsev, Frank van Swol and Laura J.D. Frink. 
264 1 |a Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) :  |b IOP Publishing,  |c [2021] 
300 |a 1 online resource (various pagings) :  |b illustrations (some color). 
336 |a text  |2 rdacontent 
337 |a electronic  |2 isbdmedia 
338 |a online resource  |2 rdacarrier 
490 1 |a [IOP release $release] 
490 1 |a IOP ebooks. [2021 collection] 
500 |a "Version: 202110"--Title page verso. 
504 |a Includes bibliographical references. 
505 0 |a 1. Introduction : a historical overview -- 1.1. Charges and fields -- 1.2. Electrostatics of systems with distributed charges -- 1.3. The concept of electric double layer 
505 8 |a part I. Theory. 2. The origin of charge at interfaces involving electrolyte solutions -- 2.1. Effects of the surface chemical reactions and the charge regulation model -- 2.2. Effects due to physical adsorption -- 2.3. Structural effects on the ionic and solvent concentration at the interface 
505 8 |a 3. Continuum models of the electric double layers -- 3.1. The Poisson-Boltzmann equation -- 3.2. Electric double layer models based on the Poisson-Boltzmann equation : exact and approximate solutions -- 3.3. Beyond the Boltzmann distribution : the semiconductor-electrolyte interface -- 3.4. Electrokinetic phenomena -- 3.5. Deficiencies of the continuum approach 
505 8 |a 4. Integral equation theory -- 4.1. Background -- 4.2. Percus-Yevick closure -- 4.3. The hypernetted-chain closure -- 4.4. The mean spherical approximation (MSA) -- 4.5. Hard sphere mixtures -- 4.6. The Ornstein-Zernike equations approach to studying electric double layers 
505 8 |a 5. Perturbation and mean field theory -- 5.1. Background -- 5.2. Virial expansions -- 5.3. Zwanzig's perturbation theory -- 5.4. Mean field theory 
505 8 |a 6. Density functional theory -- 6.1. Density functional theory for electronic structure -- 6.2. Density functional theory for classical fluids 
505 8 |a 7. Classical-DFT for electrolyte interfaces -- 7.1. Molecular models of electrolytes -- 7.2. Classical-DFT for point-charge electrolytes -- 7.3. Classical-DFT for finite-size electrolytes -- 7.4. Classical-DFT with correlations -- 7.5. Classical-DFT with cohesive interactions -- 7.6. Classical-DFT for systems with active surfaces -- 7.7. Classical-DFT for water -- 7.8. Classical-DFT for electrokinetic systems 
505 8 |a part II. Structure of a single electric double layer : effects due to surface charge regulation and non-Coulombic interactions. 8. Molecular properties of a single electric double layer -- 8.1. Classical density functional theory model of a single flat electric double layer -- 8.2. Solution structure in an electric double layer with surface charge regulation -- 8.3. Conclusions 
505 8 |a 9. Ionic solvation effects and solvent-solvent interactions -- 9.1. Solvation of the potential determining ions -- 9.2. Solvation of the positive non-potential determining ions -- 9.3. Solvation of the negative non-potential determining ions -- 9.4. Effect of the solvent-solvent fluid interactions -- 9.5. Conclusions 
505 8 |a 10. Surface solvation and non-Coulombic ion-surface interactions -- 10.1. Solvent-surface interactions. Solvophilic and solvophobic surfaces -- 10.2. Effect of the non-Coulombic interactions between the potential determining ions and the charged wall -- 10.3. Effect of the non-Coulombic positive ions--surface interactions -- 10.4. Effect of the non-Coulombic negative ions--surface interactions -- 10.5. Conclusions 
505 8 |a 11. The potential distribution in the electric double layer and its relationship to the fluid charge -- 11.1. The Poisson equation for structured electrolyte solutions -- 11.2. Molecular interpretation of the Helmholtz planes, the Stern-Grahame layer, and the electrokinetic shear plane -- 11.3. Conclusions 
505 8 |a 12. Electric double layers containing multivalent ions -- 12.1. Multivalent ion density profiles in the electric double layer -- 12.2. Effect of the non-potential-determining ions valency on the density profiles of the potential determining ions in the electric double layer -- 12.3. Non-Coulombic surface interactions, charge and potential distributions in the Stern-Grahame layer and beyond -- 12.4. Conclusions 
505 8 |a 13. Ionic size effects -- 13.1. Ionic size variations and solution density -- 13.2. Conclusions 
505 8 |a part III. Numerical methods. 14. Molecular simulation : methods -- 14.1. Background -- 14.2. Molecular dynamics methods -- 14.3. The potential distribution theorem (PDT) -- 14.4. Simulation routes to the grand potential 
505 8 |a 15. Molecular simulation : applications -- 15.1. Background -- 15.2. One-component plasma -- 15.3. Molten salts -- 15.4. Bulk electrolytes 
505 8 |a 16. Numerical methods for classical-DFT -- 16.1. Solution methods -- 16.2. Algorithms for constructing phase diagrams. 
520 3 |a The electrical double layer describes charge and potential distributions that form at the interface between electrolyte solutions and the surface of an object, and they play a fundamental role in chemical and electrochemical behaviour. Colloid science, electrochemistry, material science, and biology are a few examples where such interfaces play a crucial role. The focus of this book is on the application of modern liquid state theories to the properties of electric double layers, where it demonstrates the ability of statistical mechanical approaches, such as the classical density functional theory, to provide insights and details that will enable a better and more quantitative understanding of electric double layers. The book will be essential reading for advanced students and researchers in interfacial science and its numerous applications. 
521 |a Researchers. 
530 |a Also available in print. 
538 |a Mode of access: World Wide Web. 
538 |a System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader. 
545 |a Dr. Dimiter N. Petsev received his PhD in Physical Chemistry from the University of Sofia.Dr Frank van Swol received his PhD in Physical Chemistry from the University of Amsterdam, The Netherlands, where he was supervised by Prof. L.V. Woodcock. Dr. Laura J. Douglas Frink received her PhD in Chemical Engineering from the University of Illinois at Urbana-Champaign in 1995 where she was advised by Frank van Swol and Charles Zukoski. 
588 0 |a Title from PDF title page (viewed on November 8, 2021). 
650 0 |a Electric double layer. 
650 0 |a Surface chemistry. 
650 7 |a Electrochemistry & magnetochemistry.  |2 bicssc 
650 7 |a Materials.  |2 bisacsh 
700 1 |a Swol, Frank van,  |e author. 
700 1 |a Frink, Laura J. D.,  |e author. 
710 2 |a Institute of Physics (Great Britain),  |e publisher. 
776 0 8 |i Print version:  |z 9780750322744  |z 9780750322775 
830 0 |a IOP (Series).  |p Release 21. 
830 0 |a IOP ebooks.  |p 2021 collection. 
856 4 0 |u https://iopscience.uam.elogim.com/book/978-0-7503-2276-8  |z Texto completo