## 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 677

To proceed it is often assumed that the total potential energy of the system can be

simply written as a sum of interactions between every

system, that is It is important, however, to recognize the existence of three-, four-,

...

To proceed it is often assumed that the total potential energy of the system can be

simply written as a sum of interactions between every

**pair**of molecules in thesystem, that is It is important, however, to recognize the existence of three-, four-,

...

Page 681

In a monatomic liquid the lifetime over which any given

regarded as nearest neighbours is of the order of a few picoseconds. (See

Section 11.5.) Some examples of g(r) are given in Figs 11.3.1-11.3.3. The result

for ...

In a monatomic liquid the lifetime over which any given

**pair**of molecules can beregarded as nearest neighbours is of the order of a few picoseconds. (See

Section 11.5.) Some examples of g(r) are given in Figs 11.3.1-11.3.3. The result

for ...

Page 683

For liquid water, the coordination number is about four and is almost independent

of temperature in the range 0-200 °C (Narton and Levy 1972). Another familiar

example of

For liquid water, the coordination number is about four and is almost independent

of temperature in the range 0-200 °C (Narton and Levy 1972). Another familiar

example of

**pair**correlation functions is that between ions in a bulk electrolyte.### What people are saying - Write a review

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### Contents

INTRODUCTION TO STATISTICAL MECHANICS | 675 |

ADSORPTION FROM SOLUTION | 709 |

THE ELECTROKINETIC EFFECTS | 786 |

Copyright | |

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### Common terms and phrases

adsorbed adsorption approximation assumed average behaviour bulk calculated Chapter Chem co-surfactant coagulation coalescence Colloid interface Sci colloidal dispersion colloidal particles compare with eqn component constant correlation function corresponding counterions diameter diffuse dilute double layer droplets effect electrical electrokinetic electrolyte electrostatic emulsion equilibrium Establish eqn estimate Exercise experimental Faraday ferrofluid field film flow fluid force free energy given hard sphere head group Hunter hydrophilic increases interaction ion density latex linear liquid magnetic measured micelles microemulsion molecules neutron Newtonian fluid non-ionic surfactant Note obtained occur Ottewill Overbeek pair parameters phase Phys plane polymer potential potential determining ions pressure procedure pseudoplastic radius region repulsion result scattering shear rate shear stress shown in Fig solution specific adsorption spherical stability surface charge surfactant suspension temperature thermodynamic thin thixotropic values velocity visco-elastic viscometer viscosity volume fraction Waals zero