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10 - Self assembly in theory and practice

from Part II - Self assembly

Published online by Cambridge University Press:  06 January 2011

Barry W. Ninham  and
Pierandrea Lo Nostro
Barry W. Ninham
Affiliation:
Australian National University, Canberra
Pierandrea Lo Nostro
Affiliation:
Università degli Studi di Firenze, Italy
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Summary

Ideas and defects of theories of self assembly

As already remarked, the first attempts to build such a unified molecular theory of self assembly that could embrace all possible aggregates began 30 years ago.

It began with Tanford's ideas on opposing intramolecular forces between surfactant molecules at interfaces.

A theory via statistical mechanics was developed based on minimal assumptions. This theory is just a characterization of self assembly. It is more complicated than, but at the same level as, nucleation theory for gas–liquid phase transitions. (Nucleation theory considers only the growth of spherical aggregates, droplets of liquid in a vapour. With surfactants we have to consider a multitude of possible aggregates of different shapes.) Nonetheless, as we have seen, the characterization that emerged gave out a set of simple design rules to predict microstructure for dilute systems.

In outline the ideas involved are these:

In the processes involved in formation of an aggregate there are several factors that can be identified.

There is a hydrophobic free energy of transfer of a monomer surfactant hydrocarbon tail, from water to the assumed bulk oil-like environment in its associated state. In an aggregate at its interface the forces between the hydrocarbon tails oppose the intra-aggregate headgroup interactions (see Fig. 10.1). These forces could be ionic, hydration, zwitterionic or steric forces. This competition at the interface sets the interfacial curvature. There is then an interfacial free energy contribution augmented by curvature contributions.

Type
Chapter
Information
Molecular Forces and Self Assembly
In Colloid, Nano Sciences and Biology
 , pp. 293 - 307
Publisher: Cambridge University Press
Print publication year: 2010

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