Epitaxial self-organization: from surfaces to magnetic materials

TL;DR

This paper reviews how self-organization techniques are used to study and enhance magnetic materials, offering insights into low-dimensional magnetic phenomena and potential device applications beyond lithography.

Contribution

It provides a comprehensive overview of self-organization in magnetic materials, highlighting its advantages over lithography for studying low-dimensional effects and developing new functionalities.

Findings

Self-organization enables the study of magnetic phenomena in low-dimensional systems.

Thick self-organized structures can mitigate superparamagnetism.

Self-organization can tailor magnetic anisotropy and property dispersion.

Abstract

Self-organization of magnetic materials is an emerging and active field. An overview of the use of self-organization for magnetic purposes is given, with a view to illustrate aspects that cannot be covered by lithography. A first set of issues concerns the quantitative study of low-dimensional magnetic phenomena (1D and 0D). Such effects also occur in microstructured and lithographically-patterned materials but cannot be studied in these because of the complexity of such materials. This includes magnetic ordering, magnetic anisotropy and superparamagnetism. A second set of issues concerns the possibility to directly use self-organization in devices. Two sets of examples are given: first, how superparamagnetism can be fought by fabricating thick self-organized structures, and second, what new or improved functionalities can be expected from self-organized magnetic systems, like the tailoring of magnetic anisotropy or controlled dispersion of properties.