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Electromechanical characterization of polyelectrolyte gels by indentation

Electromechanical characterization of polyelectrolyte gels by indentation
Electromechanical characterization of polyelectrolyte gels by indentation
We report an indentation method to quantify the electromechanical coupling in polyelectrolyte gels (PGs). PGs produce electric fields in response to mechanical stress and are therefore promising for mechanical sensor applications. The method exposes thin gel samples to well-defined pressure distributions through a spherical indentor, while the electrical response is measured with an array of platinum electrodes embedded in the support. A series of copolymer gels of acrylamide and acrylic acid were synthesized and equilibrated at a fixed pH, leading to samples with systematically varying spatial densities of both charged groups and cross-links. They were characterized by measuring the potential difference between the gel and the equilibrating solution (Donnan potential) as well as their electromechanical coupling through the indentation method. The electromechanical coupling was found to be proportional to the Donnan potential, while the latter is a universal function of the spatial density of ionizable groups in the gel, irrespective of the cross-link density.
511-517
Prudnikova, Katsiaryna
962af200-b8b4-478c-835b-c26c61f1114e
Utz, Marcel
c84ed64c-9e89-4051-af39-d401e423891b
Prudnikova, Katsiaryna
962af200-b8b4-478c-835b-c26c61f1114e
Utz, Marcel
c84ed64c-9e89-4051-af39-d401e423891b

Prudnikova, Katsiaryna and Utz, Marcel (2010) Electromechanical characterization of polyelectrolyte gels by indentation. Macromolecules, 43 (1), 511-517. (doi:10.1021/ma901899m).

Record type: Article

Abstract

We report an indentation method to quantify the electromechanical coupling in polyelectrolyte gels (PGs). PGs produce electric fields in response to mechanical stress and are therefore promising for mechanical sensor applications. The method exposes thin gel samples to well-defined pressure distributions through a spherical indentor, while the electrical response is measured with an array of platinum electrodes embedded in the support. A series of copolymer gels of acrylamide and acrylic acid were synthesized and equilibrated at a fixed pH, leading to samples with systematically varying spatial densities of both charged groups and cross-links. They were characterized by measuring the potential difference between the gel and the equilibrating solution (Donnan potential) as well as their electromechanical coupling through the indentation method. The electromechanical coupling was found to be proportional to the Donnan potential, while the latter is a universal function of the spatial density of ionizable groups in the gel, irrespective of the cross-link density.

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More information

e-pub ahead of print date: 16 November 2009
Published date: 2010
Organisations: Magnetic Resonance

Identifiers

Local EPrints ID: 354821
URI: http://eprints.soton.ac.uk/id/eprint/354821
DOI: doi:10.1021/ma901899m
PURE UUID: 17e41727-8a38-463f-bb68-a365711e5e3a
ORCID for Marcel Utz: ORCID iD orcid.org/0000-0003-2274-9672

Catalogue record

Date deposited: 23 Jul 2013 11:25
Last modified: 15 Mar 2024 03:44

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Contributors

Author: Katsiaryna Prudnikova
Author: Marcel Utz ORCID iD

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