Switchable Electrostatically Templated Polymerization

Chendan Li; Jose R. Magana; Fabian Sobotta; Junyou Wang; Martien A. Cohen Stuart; Bas van Ravensteijn; Ilja K Voets

doi:10.1002/anie.202206780

Switchable Electrostatically Templated Polymerization

Chendan Li, Jose R. Magana, Fabian Sobotta, Junyou Wang, Martien A. Cohen Stuart, Bas van Ravensteijn (Corresponding author), Ilja K Voets

Research output: Contribution to journal › Article › Academic › peer-review

8 Citations (Scopus)

133 Downloads (Pure)

Abstract

We report a switchable templated polymerization system where the strength of the templating effect can be modulated by solution pH and/or ionic strength. The responsiveness to these cues is incorporated through a dendritic polyamidoamine-based template of which the charge density depends on pH. The dendrimers act as a template for the polymerization of an oppositely charged monomer, namely sodium styrene sulfonate. We show that the rate of polymerization and maximum achievable monomer conversion are directly related to the charge density of the template, and hence the environmental pH. The polymerization could effectively be switched 'ON' and 'OFF' on demand, by cycling between acidic and alkaline reaction environments. These findings break ground for a novel concept, namely harnessing co-assembly of a template and growing polymer chains with tunable association strength to create and control coupled polymerization and self-assembly pathways of (charged) macromolecular building blocks.

Original language	English
Article number	e202206780
Number of pages	6
Journal	Angewandte Chemie - International Edition
Volume	61
Issue number	39
Early online date	29 Jun 2022
DOIs	https://doi.org/10.1002/anie.202206780
Publication status	Published - 26 Sept 2022

Funding

Funders	Funder number
Marie Skłodowska‐Curie	201906740077
European Union's Horizon 2020 - Research and Innovation Framework Programme	838585
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	731.017.407, 723.014.006

Keywords

Complex Core Coacervate Micelles
PIESA
Polyelectrolytes
RAFT Polymerization
Templated Polymerizations

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title = "Switchable Electrostatically Templated Polymerization",

abstract = "We report a switchable templated polymerization system where the strength of the templating effect can be modulated by solution pH and/or ionic strength. The responsiveness to these cues is incorporated through a dendritic polyamidoamine-based template of which the charge density depends on pH. The dendrimers act as a template for the polymerization of an oppositely charged monomer, namely sodium styrene sulfonate. We show that the rate of polymerization and maximum achievable monomer conversion are directly related to the charge density of the template, and hence the environmental pH. The polymerization could effectively be switched 'ON' and 'OFF' on demand, by cycling between acidic and alkaline reaction environments. These findings break ground for a novel concept, namely harnessing co-assembly of a template and growing polymer chains with tunable association strength to create and control coupled polymerization and self-assembly pathways of (charged) macromolecular building blocks.",

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AU - Magana, Jose R.

AU - Sobotta, Fabian

AU - Wang, Junyou

AU - Cohen Stuart, Martien A.

AU - van Ravensteijn, Bas

AU - Voets, Ilja K

PY - 2022/9/26

Y1 - 2022/9/26

N2 - We report a switchable templated polymerization system where the strength of the templating effect can be modulated by solution pH and/or ionic strength. The responsiveness to these cues is incorporated through a dendritic polyamidoamine-based template of which the charge density depends on pH. The dendrimers act as a template for the polymerization of an oppositely charged monomer, namely sodium styrene sulfonate. We show that the rate of polymerization and maximum achievable monomer conversion are directly related to the charge density of the template, and hence the environmental pH. The polymerization could effectively be switched 'ON' and 'OFF' on demand, by cycling between acidic and alkaline reaction environments. These findings break ground for a novel concept, namely harnessing co-assembly of a template and growing polymer chains with tunable association strength to create and control coupled polymerization and self-assembly pathways of (charged) macromolecular building blocks.

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Switchable Electrostatically Templated Polymerization

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