## Foundations of Colloid Science, Volume 2 |

### From inside the book

Results 1-3 of 36

Page 827

7 . 17 ) is given in the Percus - Yevick approximation by pkT Xt = [ ( 1 - 0 ) 2 / ( 1 +

20 ) ] 2 ( 14 . 1 . 1 ) where p is the number density of particles of diameters in the

suspension , and Q = np83 / 6 ( 14 . 1 . 2 ) is the

7 . 17 ) is given in the Percus - Yevick approximation by pkT Xt = [ ( 1 - 0 ) 2 / ( 1 +

20 ) ] 2 ( 14 . 1 . 1 ) where p is the number density of particles of diameters in the

suspension , and Q = np83 / 6 ( 14 . 1 . 2 ) is the

**fraction**of the total**volume**...Page 839

Numerical calculations show that this breakdown of the MSA may occur at

structure of a fluid of hard spheres of diameter 8 , at the same

simply ...

Numerical calculations show that this breakdown of the MSA may occur at

**volume fractions**as high as 20 % in many ... we may trivially calculate thestructure of a fluid of hard spheres of diameter 8 , at the same

**volume fraction**bysimply ...

Page 916

5 % ) — surfactant ( 5 % ) , near | ( a ) Oil 804 11

w ( D ) Yow ( mN m ' ) YoiD - W no ... phase diagram ( Roman numerals refer to

number of separate co - existing phases ) ; ( b )

5 % ) — surfactant ( 5 % ) , near | ( a ) Oil 804 11

**Volume fraction**Water ( °C ) Yo -w ( D ) Yow ( mN m ' ) YoiD - W no ... phase diagram ( Roman numerals refer to

number of separate co - existing phases ) ; ( b )

**volume fractions**of phases for 0 .### What people are saying - Write a review

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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