posted on 2022-02-24, 15:59authored byKalani Moore, Eoghan N. O'Connell, Sinéad M. Griffin, Clive Downing, Louise Colfer, Michael Schmidt, Valeria Nicolosi, Ursel Bangert, Lynette Keeney, Michele A. Conroy
Multiferroic topologies are an emerging solution for future low-power magnetic nanoelectronics due to their
combined tuneable functionality and mobility. Here, we show that in addition to being magnetoelectric multiferroic at room
temperature, thin-film Aurivillius phase Bi6TixFeyMnzO18 is an ideal material platform for both domain wall and vortex topology based nanoelectronic devices. Utilizing atomic-resolution electron microscopy, we reveal the presence and structure of 180°-type
charged head-to-head and tail-to-tail domain walls passing throughout the thin film. Theoretical calculations confirm the subunit cell
cation site preference and charged domain wall energetics for Bi6TixFeyMnzO18. Finally, we show that polar vortex-type topologies
also form at out-of-phase boundaries of stacking faults when internal strain and electrostatic energy gradients are altered. This study
could pave the way for controlled polar vortex topology formation via strain engineering in other multiferroic thin films. Moreover,
these results confirm that the subunit cell topological features play an important role in controlling the charge and spin state of
Aurivillius phase films and other multiferroic heterostructures.
History
Publication
Applied Materials and Interfaces;14, pp. 5525-5536