Superhydrophobic Surfaces | Alain Carre, Kash L. Mittal | Taylor & Fra

ABSTRACT

Superhydrophobic surfaces (water contact angles higher than 150a ) can only be achieved by a combination of hydrophobicity (low surface energy materials) with appropriate surface texture. In nature one can find an array of impressive and elegant examples of superhydrophobic surfaces. For example, on a lotus leaf rain drops bounce off after impact,

TABLE OF CONTENTS

part |2 pages

Part 1: Fundamentals of Superhydrophobicity

chapter |16 pages

Fabrication of Superhydrophobic Surfaces

chapter |20 pages

Ultra-hydrophobicity Through Stochastic Surface Roughness

chapter |12 pages

Optimizing Super-Hydrophobic Surfaces: Criteria for Comparison of Surface Topographies

chapter |22 pages

Hydrophobicity of Surfaces with Cavities: Making Hydrophobic Substrates from Hydrophilic Materials?

chapter |18 pages

Dynamics of Fakir Liquids: From Slip to Splash

chapter |18 pages

Static and Dynamic Wetting Characteristics of Nano-patterned Surfaces

part |2 pages

Part 2: Superhydrophobic Surfaces from Polymers

chapter |8 pages

Wettability Alteration of Polymer Surfaces Produced by Scraping

chapter |8 pages

Surface Properties of Honeycomb and Pincushion Structures of Various Hydrophobic Polymer Materials Prepared by Self-Organization

chapter |12 pages

Hydrophobic and Superhydrophobic Polyphosphazenes

chapter |14 pages

Superhydrophobic Fluorinated Polyurethane Films

chapter |12 pages

A Simple Approach for Fabricating a Superhydrophobic Surface Based on Poly(methyl methacrylate)

chapter |12 pages

Superhydrophobic Polyethylene Films by Catalytic Ethylene Polymerization

chapter |22 pages

Plasma-Treated Superhydrophobic Polyethylene Surfaces: Fabrication, Wetting and Dewetting Properties

chapter |18 pages

Generation and Characterization of Super-Hydrophobic Micro- and Nano-structured Surfaces

chapter |16 pages

Reversibly Photo-Responsive Polymer Surfaces for Controlled Wettability

chapter |8 pages

Superhydrophobic Metallic Surfaces and Their Wetting Properties

chapter |20 pages

A Review of Recent Results on Superhydrophobic Materials Based on Micro- and Nanofibers

part |2 pages

Part 3: Superhydrophobic Surfaces from Silanes, Colloids, Particles or Sol–Gel Processes

chapter |14 pages

Superhydrophobic Silicone Nanofilament Coatings

chapter |8 pages

A Translucent and Superhydrophobic Surface Prepared with a Sol–Gel Method Based on Alumina Nanoparticles

chapter |12 pages

Fabrication and Superhydrophobic Behavior of Fluorinated Silica Nanosphere Arrays

chapter |12 pages

UV-Resistant and Superhydrophobic Self-Cleaning Surfaces Using Sol–Gel Processes

chapter |18 pages

Wettability and Superhydrophobicity of 2-D Ordered Nano-structured Arrays Based on Colloidal Monolayers

chapter |8 pages

Effects of Various Additives during Hot Water Treatment on the Formation of Alumina Thin Films for Superhydrophobic Surfaces

chapter |10 pages

Polybenzoxazine–Silica Hybrid Surface with Environmentally Responsive Wettability Behavior

chapter |14 pages

Wettability of Rough Polymer, Metal and Oxide Surfaces as well as of Composite Surfaces

part |2 pages

Part 4: Superhydrophobic Surfaces from Electrochemical Processes

chapter |22 pages

Electrochemical Fabrication of Superhydrophobic Surfaces on Metal and Semiconductor Substrates

chapter |14 pages

Fabrication of Superhydrophobic Surfaces by Electropolymerization of Thiophene and Pyrrole Derivatives

chapter |14 pages

Wettability of Methacrylate Copolymer Films Deposited on Anodically Oxidized and Roughened Aluminium Surfaces

part |2 pages

Part 5: Applications and New Insights

chapter |26 pages

Recent Approaches to Highly Hydrophobic Textile Surfaces

chapter |10 pages

Superhydrophobic Coatings for Microdevices

chapter |16 pages

Electrowetting on Superhydrophobic Surfaces: Present Status and Prospects

chapter |10 pages

Wetting of Single and Mixed Surfactant Solutions on Superhydrophobic Surfaces

chapter |12 pages

Characterisation of Wetting by Solidification of Agarose Solution Sessile Drops

chapter |11 pages

The Role of Adaptive-Deformation of Water Strider Leg in Its Walking on Water