## Foundations of Colloid Science, Volume 2 |

### From inside the book

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Page 834

5 Use the previous result to find the time taken by a polystyrene sphere of

moves in a straight line . ( Take the density of polystyrene to be 950 kg / mo . ) ...

5 Use the previous result to find the time taken by a polystyrene sphere of

**diameter**234 nm to travel 1**diameter**in a suspension at T = 298 K , assuming itmoves in a straight line . ( Take the density of polystyrene to be 950 kg / mo . ) ...

Page 858

The average interparticle distance in such a dispersion is large , relative to the

particle

low screening ( see Section 14 . 1 ) . Since the interaction between charged ...

The average interparticle distance in such a dispersion is large , relative to the

particle

**diameter**, because of the long range of the potential under conditions oflow screening ( see Section 14 . 1 ) . Since the interaction between charged ...

Page 859

leading to it are based on the assumption that the

good an assumption this is depends on how much the interparticle potential

varies with the particle

construction ...

leading to it are based on the assumption that the

**diameter**plays no role . Howgood an assumption this is depends on how much the interparticle potential

varies with the particle

**diameters**. Returning to our conceptual two - stepconstruction ...

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### Contents

Contents of Volume I | 675 |

ADSORPTION FROM SOLUTION | 709 |

THE STRUCTURE OF CONCENTRATED | 827 |

Copyright | |

5 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 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 temperature theory thin usually values viscosity volume zero