Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions

Within a colloidal dispersion, the presence of negatively adsorbing material can produce a variety of effects on the dispersion properties and interactions. With increasing concentration, the negatively adsorbing material induces both depletion and structural forces on the dispersion, which can dram...

Full description

Bibliographic Details
Main Author: James, Gregory Keith
Other Authors: Chemical Engineering
Format: Others
Published: Virginia Tech 2013
Subjects:
Online Access:http://hdl.handle.net/10919/24764
id ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-24764
record_format oai_dc
spelling ndltd-VTETD-oai-vtechworks.lib.vt.edu-10919-247642020-09-29T05:36:30Z Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions James, Gregory Keith Chemical Engineering Ducker, William A. Walz, John Y. Davis, Richey M. Martin, Stephen Michael Colloidal Dispersions Depletion and Structural Forces Colloidal Stability Atomic Force Microscopy Within a colloidal dispersion, the presence of negatively adsorbing material can produce a variety of effects on the dispersion properties and interactions. With increasing concentration, the negatively adsorbing material induces both depletion and structural forces on the dispersion, which can dramatically affect both colloidal stability and near-contact hydrodynamics. This project focused on expanding our understanding of the effects of such negatively adsorbing materials on both equilibrium and dynamic interactions between particles. The effects of charged, hard spheres (silica nanoparticle) on the hydrodynamic drag force a particle experiences as it approaches a flat plate were measured experimentally using colloid probe atomic force microscopy (CP-AFM). Deviation was found between the measured drag force and predictions for the drag force in a simple, Newtonian fluid. The measured drag force was always smaller than the predicted drag force as the particle approached contact with the plate. An effective viscosity, that approached the dispersing fluid viscosity at contact and the bulk viscosity at large separations, was determined for the system. This effective viscosity displayed similar characteristics to those predicted theoretically by Bhattacharya and Blawzdziewicz (J. Chem. Phys. 2008, 128, 214704.). The effects of both anionic and cationic micelles on the depletion and structural forces in a colloidal dispersion were studied both experimentally (with CP-AFM) and theoretically. The depletion and structural forces between a microparticle and a flat plate were measured and compared with the depletion force predicted by the force-balance model of Walz and Sharma (J. Colloid Interface Sci. 1994, 168, 485-496.). Consistent with previous work, the measured depletion force for both micelles was smaller in magnitude than that predicted by the Walz and Sharma model for hard, charged spheres. It is theorized that rearrangement of the micelle surfaces charges or physical deformation of the micelles may be responsible for the observed result. An effective surface potential for the micelles is proposed as a correction to the Walz and Sharma model. Finally, the stability of colloidal dispersions was studied macroscopically in solutions of ionic micelles. The colloidal dispersions displayed clear flocculation behavior in both cationic and anionic micelles. This flocculation behavior was compared with energy profiles determined from CP-AFM experiments between a single particle and a flat plate. A simple phase diagram was proposed for predicting the stability of colloidal dispersions based solely on the depth of the depletion energy well and the height of the repulsive energy barrier. Ph. D. 2013-12-20T09:00:14Z 2013-12-20T09:00:14Z 2013-12-19 Dissertation vt_gsexam:1876 http://hdl.handle.net/10919/24764 In Copyright http://rightsstatements.org/vocab/InC/1.0/ ETD application/pdf application/pdf Virginia Tech
collection NDLTD
format Others
sources NDLTD
topic Colloidal Dispersions
Depletion and Structural Forces
Colloidal Stability
Atomic Force Microscopy
spellingShingle Colloidal Dispersions
Depletion and Structural Forces
Colloidal Stability
Atomic Force Microscopy
James, Gregory Keith
Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions
description Within a colloidal dispersion, the presence of negatively adsorbing material can produce a variety of effects on the dispersion properties and interactions. With increasing concentration, the negatively adsorbing material induces both depletion and structural forces on the dispersion, which can dramatically affect both colloidal stability and near-contact hydrodynamics. This project focused on expanding our understanding of the effects of such negatively adsorbing materials on both equilibrium and dynamic interactions between particles. The effects of charged, hard spheres (silica nanoparticle) on the hydrodynamic drag force a particle experiences as it approaches a flat plate were measured experimentally using colloid probe atomic force microscopy (CP-AFM). Deviation was found between the measured drag force and predictions for the drag force in a simple, Newtonian fluid. The measured drag force was always smaller than the predicted drag force as the particle approached contact with the plate. An effective viscosity, that approached the dispersing fluid viscosity at contact and the bulk viscosity at large separations, was determined for the system. This effective viscosity displayed similar characteristics to those predicted theoretically by Bhattacharya and Blawzdziewicz (J. Chem. Phys. 2008, 128, 214704.). The effects of both anionic and cationic micelles on the depletion and structural forces in a colloidal dispersion were studied both experimentally (with CP-AFM) and theoretically. The depletion and structural forces between a microparticle and a flat plate were measured and compared with the depletion force predicted by the force-balance model of Walz and Sharma (J. Colloid Interface Sci. 1994, 168, 485-496.). Consistent with previous work, the measured depletion force for both micelles was smaller in magnitude than that predicted by the Walz and Sharma model for hard, charged spheres. It is theorized that rearrangement of the micelle surfaces charges or physical deformation of the micelles may be responsible for the observed result. An effective surface potential for the micelles is proposed as a correction to the Walz and Sharma model. Finally, the stability of colloidal dispersions was studied macroscopically in solutions of ionic micelles. The colloidal dispersions displayed clear flocculation behavior in both cationic and anionic micelles. This flocculation behavior was compared with energy profiles determined from CP-AFM experiments between a single particle and a flat plate. A simple phase diagram was proposed for predicting the stability of colloidal dispersions based solely on the depth of the depletion energy well and the height of the repulsive energy barrier. === Ph. D.
author2 Chemical Engineering
author_facet Chemical Engineering
James, Gregory Keith
author James, Gregory Keith
author_sort James, Gregory Keith
title Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions
title_short Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions
title_full Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions
title_fullStr Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions
title_full_unstemmed Investigation of Hydrodynamic and Depletion Interactions in Binary Colloidal Dispersions
title_sort investigation of hydrodynamic and depletion interactions in binary colloidal dispersions
publisher Virginia Tech
publishDate 2013
url http://hdl.handle.net/10919/24764
work_keys_str_mv AT jamesgregorykeith investigationofhydrodynamicanddepletioninteractionsinbinarycolloidaldispersions
_version_ 1719344051364298752