Molecular Assembly in Block Copolymer-Surfactant Nanoparticle Dispersions: Information on Molecular Exchange and Apparent Solubility from High-Resolution and PFG NMR.

Watson Loh,Lennart Piculell,Olle Söderman,Daniel Topgaard,Guilherme A Ferreira

doi:10.3390/polym13193265

Watson Loh, Lennart Piculell + Show 3 more

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https://doi.org/10.3390/polym13193265

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Journal: Polymers	Publication Date: Sep 25, 2021
Citations: 4	License type: CC BY 4.0

Affiliation: Universidade Estadual de Campinas, Lund University

Abstract

Internally structured block copolymer-surfactant particles are formed when the complex salts of ionic-neutral block copolymers neutralized by surfactant counterions are dispersed in aqueous media. Here, we report the 1H NMR signal intensities and self-diffusion coefficients (D, from pulsed field gradient nuclear magnetic resonance, PFG NMR) of trimethyl alkylammonium surfactant ions and the poly(acrylamide)-block-poly(acrylate) (PAAm-b-PA) polyions forming such particles. The results reveal the presence of an “NMR-invisible” (slowly exchanging) fraction of aggregated surfactant ions in the particle core and an “NMR-visible” fraction consisting of surface surfactant ions in rapid exchange with the surfactant ions dissociated into the aqueous domain. They also confirm that the neutral PAAm blocks are exposed to water at the particle surface, while the PA blocks are buried in the particle core. The self-diffusion of the polyions closely agree with the self-diffusion of a hydrophobic probe molecule solubilized in the particles, showing that essentially all copolymer chains are incorporated in the aggregates. Through centrifugation, we prepared macroscopically phase-separated systems with a phase concentrated in particles separated from a clear dilute phase. D values for the surfactant and block copolymer indicated that the dilute phase contained small aggregates (ca. 5 nm) of surfactant ions and a few anionic-neutral block copolymer chains. Regardless of the overall concentration of the sample, the fraction of block copolymer found in the dilute phase was nearly constant. This indicates that the dilute fraction represented a tail of small particles created by the dispersion process rather than a true thermodynamic solubility of the complex salts.

Highlights

Several reports have studied the electrostatic complexation between water-soluble neutral-ionic block copolymers (BCP) and oppositely charged species in solution
When D2O rather than H2O is used as the solvent, the particles slowly separate according to size by creaming
The distribution includes a fraction of small aggregates that do not separate out when the dispersion is subjected to centrifugation but remain in solution as one or a few block copolymer chains attached to one or a few surfactant ion micelles

Summary

Introduction

Several reports have studied the electrostatic complexation between water-soluble neutral-ionic block copolymers (BCP) and oppositely charged species in solution. Studies of the dispersions of the above-mentioned type of complexes have been extended by employing an alternative methodology based on the complex salt (CS) approach [11]. In the latter approach, stoichiometric block copolymer complex salts (BCPCS) free of simple ions are prepared by neutralizing the acrylic acid units of the BCP with the hydroxide salt of the alkyltrimethylammonium cationic surfactant

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