Issue 18, 2014

Inkjet printed superparamagnetic polymer composite hemispheres with programmed magnetic anisotropy

Abstract

We present the fabrication and characterization of large arrays of inkjet-printed superparamagnetic polymer composite (SPMPC) hemispherical microstructures. SPMPCs are appealing for applications in microsystems and nanorobotics due to the added functionality of polymers and the significant magnetic attributes of embedded nanostructures. SPMPC-based microarchitectures can be used to perform different functions wirelessly in various media (e.g. water, solvents) using external magnetic fields: handling and assembling small objects, delivering drugs or biomass, or sensing specific physical or chemical changes. In this work superparamagnetic magnetite nanoparticles are dispersed in SU-8 to form magnetic hemispheres. Magnetically anisotropic hemispheres as well as standard SPMPC hemispheres are fabricated. Magnetic anisotropy is programmed by applying a magnetic field during curing. The distribution of nanoparticles inside the polymer matrix and magnetic characteristics of the SPMPC are investigated. Magnetic manipulation of hemispheres is demonstrated at liquid–liquid interfaces. Different assembly strategies to form lines or geometric shapes from hemispheres as well as their independent dynamic control are demonstrated. Finally, a two-interface assembly strategy is demonstrated to assemble hemispheres into complete spheres for advanced self-assembly tasks.

Graphical abstract: Inkjet printed superparamagnetic polymer composite hemispheres with programmed magnetic anisotropy

Supplementary files

Article information

Article type
Communication
Submitted
04 Dec 2013
Accepted
22 Mar 2014
First published
01 Apr 2014
This article is Open Access
Creative Commons BY license

Nanoscale, 2014,6, 10495-10499

Author version available

Inkjet printed superparamagnetic polymer composite hemispheres with programmed magnetic anisotropy

O. Ergeneman, C. Peters, M. R. Gullo, L. Jacot-Descombes, S. Gervasoni, B. Özkale, P. Fatio, V. J. Cadarso, M. Mastrangeli, S. Pané, J. Brugger, C. Hierold and B. J. Nelson, Nanoscale, 2014, 6, 10495 DOI: 10.1039/C3NR06442E

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