Jurczyk, Jakub Mateusz

Cascales Sandoval, Miguel A.

Leo, Naemi Riccarda

Fernández-Pacheco Chicon, A.

2026-01-27T13:12:46Z

2026-01-27T13:12:46Z

2025-07-25

<div class="csl-bib-body"> <div class="csl-entry">Jurczyk, J. M., Cascales Sandoval, M. A., Leo, N. R., &#38; Fernández-Pacheco Chicon, A. (2025, July 25). <i>Towards the magneto-optical characterization of complex-shaped 3D nanostructures using dark field MOKE</i> [Presentation]. 14th Joint European Magnetic Symposia (JEMS-2025), Heidelberg, Germany. http://hdl.handle.net/20.500.12708/225724</div> </div>

http://hdl.handle.net/20.500.12708/225724

The recent development of direct 3D printing methods for complex-shape functional nanostructures, such as focused electron beam induced deposition (FEBID) and two photon lithography (TPL) has created a need for advanced characterisation techniques to assess the properties of the deposited structures. In the case of magnetic nanostructures, conventional characterisation methods typically rely on synchrotron radiation techniques, such as scanning transmission x-ray microscopy or photoelectron emission microscopy [1]. While these techniques provide valuable insight into magnetic properties of the nanostructures, they require access to large-scale facilities, which is often limited. To address this limitation, the dark field magnetooptical Kerr effect system (DF-MOKE) was introduced [2]. This technique has been successfully used to analyse the switching mechanisms of ramp-shaped nanostructures fabricated by a combination of FEBID and physical vapour deposition (PVD) [2]. Figure 1. a) A typical ramp-shaped deposit made with TPL+PVD, with inclination angle of 40°; b) A hysteresis loop from the presented nanostructure; c) Dependence of the switching fields on the structure’s inclination angles. So far, DF-MOKE has been primarily used to characterise only single nanostructures with one reflection plane. However, modern magnetic nanodevices present geometries far more complex, with multiple planes of light reflection [3,4]. In this contribution, we investigate the feasibility of using DF-MOKE to measure complex-shaped 3D nanostructures. For this purpose, simplified systems were prepared with several reflection planes using a combination of 3D nano-printing by FEBID or TPL and covered with magnetic material using PVD. The presented data will show the measurements performed on the single nanostructures and arrays in close proximity. An analysis of coercivity as a function of geometry for single structures, and a comparison with measurements obtained in arrays of similar geometries will be presented. The advantages and limitations of using DF-MOKE as an easy-access, laboratory-based tool for characterising complex- shaped 3D nanostructures will be discussed.

en

magnetism

nanotechnology

FEBID

MOKE

Towards the magneto-optical characterization of complex-shaped 3D nanostructures using dark field MOKE

Presentation

Vortrag

Presentation

M2

M8

Materials Characterization

Structure-Property Relationsship

50

50

E134-06 - Forschungsbereich Physics of three-dimensional Nanomaterials

0000-0002-0828-6889

0000-0002-3862-8472

14th Joint European Magnetic Symposia (JEMS-2025)

24-07-2025

29-07-2025

On Site

Event for scientific audience

Heidelberg

DE

Jurczyk, Jakub Mateusz

Physik, Astronomie

1030

100

no Fulltext

en

Publications

none

http://purl.org/coar/resource_type/R60J-J5BD

conference presentation

E134-06 - Forschungsbereich Physics of three-dimensional Nanomaterials

E134-06 - Forschungsbereich Physics of three-dimensional Nanomaterials

E134-06 - Forschungsbereich Physics of three-dimensional Nanomaterials

E134-06 - Forschungsbereich Physics of three-dimensional Nanomaterials

0000-0002-0828-6889

0000-0002-3862-8472

E134 - Institut für Angewandte Physik

E134 - Institut für Angewandte Physik

E134 - Institut für Angewandte Physik

E134 - Institut für Angewandte Physik