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The electrical double layer describes charge and potential distributions that form at the interface between electrolyte solutions and the surface of an object. They occur in a wide range of physical and chemical systems, where they play a fundamental role in their chemical and electrochemical behaviour. Colloid science, electrochemistry, material science, and biology are a few examples where such interfaces play a crucial role. Though first described over a hundred years ago, the study of the electrical double layer remains an important topic today. Parallel to this investigation is the rapid development of the liquid state theory, which relates molecular interactions to macroscopic thermodynamic properties.
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. It provides a systematic description of electrical double layer models and their applications, extending the coverage of continuum models found in other introductory texts, with molecular models and the effects of solvents. The book will be essential reading for advanced students and researchers in interfacial science and its applications; be they chemists, physicists, materials scientists or engineers.
Auteur
Dr Dimiter N Petsev received his PhD in Physical Chemistry from the University of Sofia. Then he holds research positions at Purdue University and the University of Alabama in Huntsville. Dr Petsev's research interests are in the area of colloids, surfaces, and interfaces. A significant part of the efforts are focused on the dynamics of charged colloids, self-assembly of ionic surfactants, and emulsion stability against flocculation and coalescence. Other research areas of interest include electrokinetic phenomena and their relation to micro and nanofluidics, and capillary-driven flow in porous materials. 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. His research has focused on the statistical mechanics of interfaces using molecular dynamics, Monte Carlo, and classical density functional theory techniques. Dr van Swol was awarded a Ramsay Memorial Fellowship, which he held at Oxford University (UK) where he worked with Prof. John S Rowlinson, from 1982 until 1985. He then joined the Chemical Engineering Department of Cornell as a visiting faculty and the University of Illinois at Urbana-Champaign before joining Sandia National Laboratories in 1994, from which he retired in 2015. He has been a Research Professor at the University of New Mexico since 1996. 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. Her doctoral work involved simulation of colloidal systems with solvation potentials from classical density functional theory (DFT). She joined Sandia National Laboratories (SNL) in 1995 to pursue the development of a general-purpose c-DFT code capable of 2- and 3-dimensional calculations using parallel computing platforms. She was a lead developer of the c-DFT code Tramonto which is currently available as open-source software. Scientific interests include colloidal systems, adsorption and wetting, polymer interfaces, and self-assembled systems with applications in nanotechnology and biology. In 2008, she left SNL and started a consulting company. She became a research professor at the University of New Mexico in 2017.
Texte du rabat
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.
Key Features
Helps to advance further research fields as colloid science, electrochemistry, material science, and physical chemistry of electrolytes.
Contenu
Preface
1 Introduction: A Historical Overview
Part I Theory
2 The Origin of Charge at Interfaces Involving Electrolyte Solutions
3 Continuum Models of the Electric Double Layers
4 Integral Equation Theory
5 Perturbation and Mean Field Theory
6 Density Functional Theory
7 Classical-DFT for Electrolyte Interfaces
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
9 Ionic Solvation Effects and Solvent-Solvent Interactions
10 Surface Solvation and Non-Coulombic Ion-Surface Interactions
11 The Potential Distribution in the Electric Double Layer and Its Relationship to the Fluid Charge
12 Electric Double Layers Containing Multivalent Ions
13 Ionic Size Effects
Part III Numerical Methods
14 Molecular Simulation: Methods
15 Molecular Simulation: Applications
16 Numerical Methods for Classical-DFT
A The Poisson-Nernst-Planck-Bikerman Theory
B MSA: Thermodynamic Properties
C Some Conventions: Dimensionless Quantities
D Details of Lekner's Mathematical Transformations
E Finite Difference and Finite Element methods for PDEs