Fundamental Principles and Practical Applications
Buch, Englisch, 299 Seiten, Format (B × H): 173 mm x 249 mm, Gewicht: 726 g
ISBN: 978-3-527-41229-7
Verlag: WILEY-VCH
Starting from the basic principles of wetting, electrowetting and fluid dynamics all the way up to those engineering aspects relevant for the development of specific devices, this is a comprehensive introduction and overview of the theoretical and practical aspects.
Written by two of the most knowledgeable experts in the field, the text covers both current as well as possible future applications, providing basic working principles of lab-on-a-chip devices and such optofluidic devices as adaptive lenses and optical switches. Furthermore, novel e-paper display technology, energy harvesting and supercapacitors as well as electrowetting in the nano-world are discussed. Finally, the book contains a series of exercises and questions for use in courses on microfluidics or electrowetting.
With its all-encompassing scope, this book will equally serve the growing community of students and academic and industrial researchers as both an introduction and a standard reference.
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Preface xi
1 Introduction to Capillarity and Wetting Phenomena 1
1.1 Surface Tension and Surface Free Energy 2
1.1.1 The Microscopic Origin of Surface Energies 2
1.1.2 Macroscopic Definition of Surface Energy and Surface Tension 5
1.2 Young–Laplace Equation: The Basic Law of Capillarity 7
1.2.1 Laplace’s Equation and the Pressure Jump Across Liquid Surfaces 7
1.2.2 Applications of the Young–Laplace Equation: The Rayleigh–Plateau Instability 11
1.3 Young–Dupré Equation: The Basic Law of Wetting 13
1.3.1 To Spread or Not to Spread: From Solid Surface Tension to Liquid Spreading 13
1.3.2 Partial Wetting: The Young Equation 16
1.4 Wetting in the Presence of Gravity 19
1.4.1 Bond Number and Capillary Length 21
1.4.2 Case Studies 22
1.4.2.1 The Shape of a Liquid Puddle 22
1.4.2.2 The Pendant Drop Method: Measuring Surface Tension by Balancing Capillary and Gravity Forces 24
1.4.2.3 Capillary Rise 25
1.5 Variational Derivation of the Young–Laplace and the Young–Dupré Equation 26
1.6 Wetting at the Nanoscale 29
1.6.1 The Effective Interface Potential 30
1.6.2 Case Studies 32
1.6.2.1 The Effective Interface Potential for van der Waals Interaction 32
1.6.2.2 Equilibrium Surface Profile Near the Three-Phase Contact Line 34
1.7 Wetting of Heterogeneous Surfaces 35
1.7.1 Young–Laplace and Young–Dupré Equation for Heterogeneous Surfaces 35
1.7.2 Gibbs Criterion for Contact Line Pinning at Domain Boundaries 37
1.7.3 From Discrete Morphology Transitions to Contact Angle Hysteresis 38
1.7.4 Optimum Contact Angle on Heterogeneous Surfaces: The Laws of Wenzel and Cassie 43
1.7.5 Superhydrophobic Surfaces 45
1.7.6 Wetting of Heterogeneous Surfaces in Three Dimensions 48
1.7.7 Wetting of Complex Surfaces in Three Dimensions: Morphology Transitions, Instabilities, and Symmetry Breaking 50
1.A Mechanical Equilibrium and Stress Tensor 55
Problems 56
References 58
2 Electrostatics 61
2.1 Fundamental Laws of Electrostatics 61
2.1.1 Electric Fields and the Electrostatic Potential 61
2.1.2 Specific Examples 64
2.2 Materials in Electric Fields 66
2.2.1 Conductors 66
2.2.2 Dielectrics 68
2.2.3 Dielectric Liquids and Leaky Dielectrics 73
2.3 Electrostatic Energy 76
2.3.1 Energy of Charges, Conductors, and Electric Fields 76
2.3.2 Capacitance Coefficients and Capacitance 78
2.3.3 Thermodynamic Energy of Charged Systems: Constant Charge Versus Constant Potential 80
2.4 Electrostatic Stresses and Forces 82
2.4.1 Global Forces Acting on Rigid Bodies 82
2.4.2 Local Forces: The Maxwell Stress Tensor 83
2.4.3 Stress Boundary Condition at Interfaces 85
2.5 Two Generic Case Studies 87
2.5.1 Parallel Plate Capacitor 87
2.5.2 Charge and Energy Distribution for Two Capacitors in Series 90
Problems 92
References 93
3 Adsorption at Interfaces 95
3.1 Adsorption Equilibrium 96
3.1.1 General Principles 96
3.1.2 Langmuir Adsorption 96
3.1.3 Reduction of Surface Tension 99
3.2 Adsorption Kinetics 101
3.3 Surface-Active Solutes: From Surfactants to Polymers, Proteins, and Particles 105
3.A A StatisticalMechanics Model of Interfacial Adsorption 107
Problems 110
References 110
4 From Electric Double Layer Theory to Lippmann’s Electrocapillary Equation 113
4.1 Electrocapillarity: the Historic Origins 113
4.2 The Electric Double Layer at Solid–Electrolyte Interfaces 115
4.2.1 Poisson–Boltzmann Theory and Gouy–Chapman Model of the EDL 116
4.2.2 Total Charge and Capacitance of the Diffuse Layer 120
4.2.3 Voltage Dependence of the Free Energy: Electrowetting 122
4.3 Shortcomings of Poisson–Boltzmann Theory and the Gouy–Chapman Model 124
4.4 Teflon–Water Interfaces: a Case Study 125
4.A StatisticalMechanics Derivation of the Governing Equations 127
Problems 130
References 130
5 Principles of Modern Electrowetting 133
5.1 The Standard Model of Electrowetting (on Dielectric) 133
5.1.1 Electrowetting Phenomenology 133
5.1.2 Macroscopic EW Response 136
5.1.3 Microscopic Structure of the Contact Line Region 138
5.2 Interpretation of the StandardModel of EW 145
5.2.1 The Electromechanical Interpretation 145
5.2.2 StandardModel of EW Versus Lippmann’s Electrocapillarity 145
5.2.3 Limitations of the Standard Model: Nonlinearities and Contact Angle Saturation 149
5.3 DC Versus AC Electrowetting 151
5.3.1 General Principles 151
5.3.2 Application Example: Parallel Plate Geometry 153
Problems 156
References 157
6 Elements of Fluid Dynamics 159
6.1 Navier–Stokes Equations 159
6.1.1 General Principles: from Newton to Navier–Stokes 160
6.1.2 Boundary Conditions 163
6.1.3 Nondimensional Navier–Stokes Equation: The Reynolds Number 166
6.1.4 Example: Pressure-Driven Flow Between Two Parallel Plates 167
6.2 Lubrication Flows 170
6.2.1 General Lubrication Flows 170
6.2.2 Lubrication Flows with a Free Liquid Surface 173
6.2.3 Application I: Linear Stability Analysis of aThin Liquid Film 174
6.2.4 Application II: Entrainment of Liquid Films 176
6.3 Contact Line Dynamics 179
6.3.1 Tanner’s Law and the Spreading of Drops on Macroscopic Scales 179
6.3.2 Surface Profiles on the Mesoscopic Scale: The Cox–Voinov Law 181
6.3.3 Dynamics of the Microscopic Contact Angle: The Molecular Kinetic Picture 182
6.3.4 Comparison to Experimental Results 183
6.4 SurfaceWaves and Drop Oscillations 185
6.4.1 SurfaceWaves 187
6.4.2 Oscillating Drops 188
6.4.3 Example: Electrowetting-Driven Excit
