Issue 32, 2021

Strain- and field-induced anisotropy in hybrid elastomers with elongated filler nanoparticles

Abstract

The implementation of anisotropy to functional materials is a key step towards future smart materials. In this work, we evaluate the influence of preorientation and sample architecture on the strain-induced anisotropy in hybrid elastomers containing covalently attached elongated magnetic filler particles. Accordingly, silica coated spindle-type hematite nanoparticles are incorporated into poly(dimethylsiloxane)-based elastomers, and two types of composite architectures are compared: on the one hand a conventional architecture of filled, covalently crosslinked elastomers, and on the other hybrid elastomers that are crosslinked exclusively by covalent attachment of the polymer chains to the particle surface. By the application of external strain and with magnetic fields, the orientational order of the elongated nanoparticles can be manipulated, and we investigate the interplay between strain, magnetic order, and orientational order of the particles by combining 2D small angle X-ray scattering experiments under strain and fields with Mössbauer spectroscopy under similar conditions, and supplementary angular-dependent magnetization experiments. The converging information is used to quantify the order in these interesting materials, while establishing a direct link between the magnetic properties and the spatial orientation of the embedded magnetic nanoparticles.

Graphical abstract: Strain- and field-induced anisotropy in hybrid elastomers with elongated filler nanoparticles

Article information

Article type
Paper
Submitted
25 Nov 2020
Accepted
16 Jul 2021
First published
29 Jul 2021
This article is Open Access
Creative Commons BY-NC license

Soft Matter, 2021,17, 7565-7584

Strain- and field-induced anisotropy in hybrid elastomers with elongated filler nanoparticles

J. Seifert, D. Günzing, S. Webers, M. Dulle, M. Kruteva, J. Landers, H. Wende and A. M. Schmidt, Soft Matter, 2021, 17, 7565 DOI: 10.1039/D0SM02104K

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