Colloidal interactions obtained from total internal reflection microscopy measurements and scattering data
Sammanfattning
The scattering of radiation can be used to extract information about the interactions between colloidal (10^{-7}-10^{-3} cm radius) particles suspended in liquids. As colloidal interactions incorporate entropic effects they are weak and while system specific they are governed by a number of general mechanisms. Colloidal interactions can be studied to some extent by direct measurements or more indirectly by inferring information from measurements of some property of the system.
In this thesis the principal experimental technique has been total internal reflection microscopy (TIRM), which is a very sensitive scattering technique. It allows for measurements of interaction energies between a single colloidal sphere and a flat surface in the area of 10^{-21} Joules. TIRM has been applied to show that high concentrations of non-ionic surfactant, often used at low concentrations to sterically stabilize colloidal particles, can cause particles to become physically attached by some bridging structure between the surface and particle. Another common stabilization mechanism widely used in colloidal systems is charge stabilization, whereby dissociated surface charges result in repulsion between particles and surfaces at low concentrations of electrolyte. Using TIRM a wide range of electrolytes and ionic strengths have been investigated, showing that the range of repulsion is given by the so-called Debye length for almost all situations that can be studied by TIRM. The exception is shown to be higher concentrations of 2:2 electrolytes, like MgSO4 and ZnSO4, in which repulsions are longer-ranged than expected.
At high electrolyte concentrations attractive van der Waals interactions become important. When the interaction involves surfaces or particles of two different materials with a solvent with properties in-between those of the two materials, it is possible that the van der Waals interaction can become repulsive. Some support for this occurring in polar solvent mixtures under special conditions has been obtained by TIRM.
Small colloidal particles can be used to induce effective interactions between larger particles and surfaces. A widely studied mechanism is depletion, which results from the imbalance in osmotic pressure when two surfaces come close enough together to exclude the small "depletant" spheres from the gap in between. TIRM was used to study the effect of concentration of charged depletant spheres and electrolyte on the depletion-like structural interactions between a large colloidal sphere and a flat surface. At high depletant concentrations an attraction is observed followed by a repulsive barrier as a function of separation distance, which is modeled using integral equation theory. Integral equation theory has also been used in modeling the interactions between oil-swollen surfactant micelles, so-called microemulsion droplets, based on non-ionic surfactant in water. Small-angle X-ray scattering data for a range of droplet concentrations were shown to be well described by a model based on an effective hard-sphere interaction, i.e. a short-ranged highly repulsive interaction, which is an example of an indirect method of obtaining information on colloidal interactions.
Delarbeten
Surfactant effects on colloidal interactions: Concentrated micellar solutions of nonionic surfactant, M. Nayeri, R. Karlsson, J. Bergenholtz,
Colloids and Surfaces A: Physicochemical and Engineering Aspects, 368, 84-90 (2010)
::doi::10.1016/j.colsurfa.2010.07.016 Measurements of screening length in salt solutions by total internal reflection microscopy, M. Nayeri, Z. Abbas, J. Bergenholtz,
submitted to Journal of Physical Chemistry C Total internal refection microscopy measurements of low-refractive index particles suspended in polar solvent mixtures M. Nayeri, J. Bergenholtz, Unpublished manuscript Effects of salt and particle concentration on the effective wall-sphere interaction in charged colloidal particle mixtures, M. Nayeri, J. Nordstr om, J. Bergenholtz, Unpublished manuscript Scattering Functions of Core-Shell-Structured Hard Spheres with Schulz-Distributed Radii,
M. Nayeri, M. Zackrisson, J. Bergenholtz,
Journal of Physical Chemistry B, 113, 8296-8302 (2009)
::doi::10.1021/jp811482w
Examinationsnivå
Doctor of Philosophy
Universitet
University of Gothenburg. Faculty of Science
Institution
Department of Chemistry ; Institutionen för kemi
Disputation
kl 10:15 i sal KB, Kemigården 4, Göteborg
Datum för disputation
2011-06-09
E-post
moheb.nayeri@gmail.com
moheb@chem.gu.se
Datum
2011-05-18Författare
Nayeri, Moheb
Nyckelord
total internal reflection microscopy
colloidal stability
van der Waals interaction
Debye length
surfactants
depletion
scattering
Publikationstyp
Doctoral thesis
ISBN
978-91-628-8314-0
Serie/rapportnr.
Göteborg
Språk
eng