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Behaviour of uniformly dimpled colloidal particles

Abstract:

Uniformly dimpled colloidal particles are studied using laser scanning confocal microscopy and optical tweezing, alongside real-space image analysis. In particular, a comparison is made between the behaviour of these particles with that of isotropic spherical particles of the same size and polydispersity.

We begin by detailing the synthetic techniques as well as the methods used for both experiments and simulations in this work. We then probe the structures and ordering exhibited by the dimpled particles and their spherical counterparts at a single featureless wall. Only the first layer at the wall is observed, and pronounced differences in both the translational and orientational order between the two types of particle is found. Furthermore, we show that the presence of the dimple leads to disordered structures that develop over time. Next, we reduce the dimensionality of the system to quasi-two and study the depletion induced interactions in a monolayer of colloidal particles at a single featureless wall. Using both confocal microscopy and Monte Carlo simulations, we illustrate the selectivity of the depletion interaction with regard to particle shape and polymer size. A level of complexity is then added to the problem by introducing a second colloidal system of small spherical particles. The resulting binary mixture, still with additional non-adsorbing polymer and in a monolayer at a wall, allows us to investigate so-called “lock and key” binding. We show that the inclusion of a lock particle cavity, whose shape and size is complementary to those of the key particle, significantly favours binding behaviour, which is further improved by using a depletant consisting of a small polymer and charge-screening salt. Finally, the depletion induced force between lock and key particles at contact is directly measured using optical tweezers. The dependence of the force due to depletion upon the overlap volume between the particles is illustrated, and we find that the strongest force is produced when the key is held within the cavity of the dimpled lock, demonstrating semiquantitative agreement with theoretical predictions.

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Institution:
University of Oxford
Division:
MPLS
Department:
Chemistry
Sub department:
Physical & Theoretical Chem
Research group:
Dirk Aarts
Oxford college:
Lincoln College
Role:
Author

Contributors

Division:
MPLS
Department:
Chemistry
Sub department:
Physical & Theoretical Chem
Role:
Supervisor


Publication date:
2014
DOI:
Type of award:
DPhil
Level of award:
Doctoral
Awarding institution:
University of Oxford


Language:
English
Keywords:
Subjects:
UUID:
uuid:71a4ab63-331b-4fb7-92f7-409a5b3d24b3
Local pid:
ora:9010
Deposit date:
2014-10-02
ARK identifier:

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