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Type of Document Dissertation Author Abdala, Ahmed AbdelHay Ahmed, Author's Email Address aaabdel@unity.ncsu.edu URN etd-12062002-001230 Title Solution Rheology and Microstructure of Associative Polymers Degree PhD Graduate Program Chemical Engineering Advisory Committee
Advisor Name Title Saad A. Khan Committee Chair Alan E. Tonelli Committee Co-Chair John van Zanten Committee Member Richard J. Spontak Committee Member Sam S. Hudson Committee Member Keywords
- TGA
- thermal gravimetric analysis
- creep compliance
- Clarase
- steady shear viscosity
- sticky Reptation
- sticky Rouse
- time dependent diffusion coefficient
- mean square displacement
- solubility parameter
- Nuclear magnetic resonance
- NMR
- NP surfactants
- cyclodextrinase enzymes
- Anti-icing fluids
- microrheology
- Brownian motion
- Associating polymers
- Tracer microrheology
- DSC
- differential scanning calorimetry
- dynamic frequency spectrum
- Stokes-Einstein relation
- Stokes-Einstein equation
- intrinsic viscosity
Date of Defense 2002-12-03 Availability unrestricted Abstract ABDALA, AHMED A. Solution rheology and microstructure of associative polymers(under the direction of Dr. Saad Khan and Dr. Alan Tonelli)
Water-soluble associative polymers are widely used in a variety of applications
because of their ability to modulate rheology and material microstructures. This study
focuses on understanding the structure-property relationship for hydrophobically modified
alkali soluble emulsion (HASE) polymers with emphasis on their microstructure and
rheological properties. These polymers have a complex comb-like structure that is a
polyelectrolyte backbone, a copolymer of acrylic or methacrylic acid and alkyl acrylate, with
a few hydrophobic macromonomers randomly grafted to this backbone. The hydrophobic
macromonomer consists of hydrophobic groups that are separated from the polymer chains
by polyethylene oxide (PEO) spacers. Upon neutralization, the polymer backbone adopts a
more extended conformation allowing the hydrophobic groups to associate forming a
transient network structure that enhances the solution rheological properties.
In the first part of this study, we investigate the effect of the polymer composition on
their microstructures and rheological properties. In particular, the effects of the
concentrations of methacrylic acid (MAA) and macromonomers on the solution rheology are
examined. We find that polymers with low MAA content have smaller hydrodynamic size
and weaker network structures compared to larger hydrodynamic size and stronger network
structure for polymers with high MAA content. However, due to chain increased stiffness at
higher MAA and the lower contribution from the aggregation of ethyl-acrylate groups, a
broad maximum in the viscoelastic properties of the polymer solution is observed at about 40
mole% MAA. Moreover, the material functions of polymers with different MAA content
show different concentration dependences.
In the second part of this study, co-solvents of water and propylene glycol (PG) in
different proportions are used to investigate the effect of the solvent quality on the solution
rheology of these polymers. The steady and dynamic properties show the presence of two
regimes with respect to the solvent composition. In ?water-rich? solvents, the hydrophobic
association dominates the solution rheology. In contrast, in ?PG-rich? solvents, the
hydrophobic association is suppressed due to the lower tendency of the hydrophobes to
aggregate, the smaller coil size of the polymer chains and changes in the PEO spacer
conformations. These two different types of behavior are discussed and confirmed by the
different concentration dependences in each regime.
In the third part of the study, the ability of using diffusing wave spectroscopy (DWS)
to probe the dynamics of HASE polymers is examined. We find that DWS accurately probes
the structural changes induced by the change in the solvent quality or the polymer
concentration. Moreover, comparison with conventional mechanical rheometry data reveals
excellent qualitative agreement between the data obtained from the two techniques.
Quantitatively, however, there is a discrepancy between the data obtained from each
technique. Several reasons for the discrepancy are discussed, including the possibility that the
dynamics at the micro-level could be different from the bulk properties. The scaling of the
creep compliance, high?frequency elastic modulus and relaxation time with polymer
concentration show power-law dependences. The power-law exponents are discussed in light
of theoretical predictions and available experimental data.
An approach to modulate the hydrophobic association is presented in the last part of
the study. The first step in this approach involves the addition of inclusion compound
forming hosts (?- or ?- cyclodextrin) to the polymer solution. The encapsulation of the
hydrophobic groups leads to significant reduction in the solution viscosity and viscoelastic
properties The second step requires the addition of surfactants to reactivate the hydrophobic
groups and thus recover the solution rheological properties. We are able to recover the
solution properties using different nonionic surfactants.
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