## Foundations of Colloid Science, Volume 2While Volume I stands as an essentially complete advanced textbook of colloidal science, Volume II extends the material to include important new areas, and develops some of the topics in much greater depth. An introductory chapter on the theory of liquids describes the concept of correlation functions and the use of Fourier transforms to analyse the scattering of light and neutrons by colloidal systems. Absorption is given detailed coverage and a chapter on electrokinetics introduces a new approach to time-dependent processes in the double layer. The principles of double layer theory are also used to review the behavior of thin films and emulsions. A final chapter on the rheology of colloidal suspensions calls on many of the concepts developed earlier to bring some cohesion to this important and rapidly developing field. |

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Page 779

Adsorption isotherms

adsorbate. (A) Plateaux

pack. (B) Horizontal close pack only observed. (C) Vertical close pack on the

surface ...

Adsorption isotherms

**corresponding**to different possible configurations of theadsorbate. (A) Plateaux

**corresponding**to horizontal (II) and vertical (IV) closepack. (B) Horizontal close pack only observed. (C) Vertical close pack on the

surface ...

Page 804

This

= a . The ion density disturbances then diffuse into each other , eventually

reaching a steady state in a time of order ( a ? / D ) . Thus in a thin double layer

colloid ...

This

**corresponds**to the situation described at the end of Section 13 . 5 . 2 with L= a . The ion density disturbances then diffuse into each other , eventually

reaching a steady state in a time of order ( a ? / D ) . Thus in a thin double layer

colloid ...

Page 847

Since p0 = mnv0 and the

the momentum in vacuo in terms of the kinetic energy: p0=\(2mnE0). At any point,

r, in the material, the energy will be E0+ U(r), where U(r) is given by eqn (14.3.2).

Since p0 = mnv0 and the

**corresponding**kinetic energy is mnvl/2, we may writethe momentum in vacuo in terms of the kinetic energy: p0=\(2mnE0). At any point,

r, in the material, the energy will be E0+ U(r), where U(r) is given by eqn (14.3.2).

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### Contents

Contents of Volume I | 675 |

ADSORPTION FROM SOLUTION | 709 |

THE ELECTROKINETIC EFFECTS 786 13 THE ELECTROKINETIC EFFECTS | 786 |

Copyright | |

6 other sections not shown

### Other editions - View all

Foundations of Colloid Science, Volume 1 Robert J. Hunter,Lee R. White,Derek Y. C. Chan Snippet view - 1987 |

Foundations of Colloid Science, Volume 1 Robert J. Hunter,Lee R. White,Derek Y. C. Chan Snippet view - 1987 |

### Common terms and phrases

adsorbed adsorption applied approach approximation assumed average becomes behaviour bulk calculated Chapter charge Chem Colloid interface Sci colloidal component concentration constant correlation corresponding density depends described determined developed direction discussed dispersion distance double layer droplets effect electrical electrokinetic electrolyte emulsion energy equation equilibrium estimate et al example Exercise experimental expression factor field film flow fluid force fraction function given gives groups important increases interaction interface involved ions limit liquid material measured microemulsion molecules Note observed obtained occur pair parameters particles phase positive possible potential present pressure problem procedure radius range reduces referred region result scattering Section separation shear rate shown solution specific spheres stability stress structure surface surface charge surface tension suspension theory thin usually values viscosity volume zero