Coarsening dynamics of ferromagnetic granular networks — experimental results and simulations

Author(s)
Armin Kögel, Pedro A. Sánchez, Robin Maretzki, Tom Dumont, Elena S. Pyanzina, Sofia Kantorovich, Reinhard Richter
Abstract

We investigate the phase separation of a shaken mixture of glass and magnetised steel spheres after a sudden quench of the shaker amplitude. After quenching, transient networks of steel spheres emerge in the experiment. For the developing network clusters we estimate the number of spheres in them, and the characteristic path lengths. We find that both quantities follow a log-normal distribution function. Moreover, we study the temporal evolution of the networks. In the sequence of snapshots we observe an initial regime, where the network incubates, followed by a temporal regime where network structures are elongated and broken, and finally a regime where the structures have relaxed to compact clusters of rounded shapes. This phaenomenology resembles the initial, elastic and hydrodynamic regimes observed by H. Tanaka [J. Phys.: Condens. Matter, 2000, 12, R207] during the viscoelastic phase separation for dynamically asymmetric mixtures of polymers. In order to discriminate the three regimes we investigate in the experiment order parameters like the mean number of neighbors and the efficiency of the networks. In order to capture the origin for a viscoelastic phase separation in our granular mixture, we use a simple simulation approach. Not aiming at a quantitative description of the experimental results, we rather use the simulations to define the key interactions in the experimental system. This way, we discover that along with dipolar and steric interactions, there is an effective central attraction between the magnetised spheres that is responsible for the coarsening dynamics. Our simulations show as well three regimes in the evolution of characteristic order parameters.

Organisation(s)
Computational and Soft Matter Physics
External organisation(s)
Universität Bayreuth, Ural Federal University
Journal
Soft Matter
Volume
14
Pages
1001-1015
No. of pages
15
ISSN
1744-683X
DOI
https://doi.org/10.1039/C7SM00796E
Publication date
2016
Peer reviewed
Yes
Austrian Fields of Science 2012
103015 Condensed matter, 103023 Polymer physics, 103017 Magnetism, 103029 Statistical physics
Keywords
ASJC Scopus subject areas
Condensed Matter Physics, General Chemistry
Portal url
https://ucrisportal.univie.ac.at/en/publications/763f6f42-1ed5-49b3-86c7-6f315b100394