2024 roadmap on magnetic microscopy techniques and their applications in materials science

D V Christensen, U Staub, T R Devidas, B Kalisky, K C Nowack, J L Webb, U L Andersen, A Huck, D A Broadway, K Wagner, P Maletinsky, T van der Sar, C R Du, A Yacoby, D Collomb, S Bending, A Oral, H J Hug, A-O Mandru, V Neu, H W Schumacher, S Sievers, H Saito, A A Khajetoorians, N Hauptmann, S Baumann, A Eichler, C L Degen, J McCord, M Vogel, M Fiebig, P Fischer, A Hierro-Rodriguez, S Finizio, S S Dhesi, C Donnelly, F Büttner, O Kfir, W Hu, S Zayko, S Eisebitt, B Pfau, R Frömter, M Kläui, F S Yasin, B J McMorran, S Seki, X Yu, A Lubk, D Wolf, N Pryds, D Makarov and M Poggio
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Abstract

Considering the growing interest in magnetic materials for unconventional computing, data storage, and sensor applications, there is active research not only on material synthesis but also characterisation of their properties. In addition to structural and integral magnetic characterisations, imaging of magnetisation patterns, current distributions and magnetic fields at nano- and microscale is of major importance to understand the material responses and qualify them for specific applications. In this roadmap, we aim to cover a broad portfolio of techniques to perform nano- and microscale magnetic imaging using superconducting quantum interference devices, spin centre and Hall effect magnetometries, scanning probe microscopies, x-ray- and electron-based methods as well as magnetooptics and nanoscale magnetic resonance imaging. The roadmap is aimed as a single access point of information for experts in the field as well as the young generation of students outlining prospects of the development of magnetic imaging technologies for the upcoming decade with a focus on physics, materials science, and chemistry of planar, three-dimensional and geometrically curved objects of different material classes including two-dimensional materials, complex oxides, semi-metals, multiferroics, skyrmions, antiferromagnets, frustrated magnets, magnetic molecules/nanoparticles, ionic conductors, superconductors, spintronic and spinorbitronic materials.
2024 年磁显微技术及其在材料科学中的应用路线图
考虑到人们对磁性材料在非传统计算、数据存储和传感器应用方面的兴趣与日俱增,目前不仅在材料合成方面,而且在材料特性表征方面都在积极开展研究。除了结构和整体磁性表征外,纳米和微米尺度的磁化模式、电流分布和磁场成像对于了解材料响应并使其符合特定应用要求也非常重要。在本路线图中,我们旨在利用超导量子干涉装置、自旋中心和霍尔效应磁力计、扫描探针显微镜、基于 X 射线和电子的方法以及磁光学和纳米级磁共振成像技术,对纳米和微米尺度的磁成像进行广泛的技术组合。该路线图旨在为该领域的专家和年轻一代学生提供一个单一的信息访问点,概述未来十年磁成像技术的发展前景,重点关注平面、三维和几何形状的物理学、材料科学和化学、重点介绍不同材料类别的平面、三维和几何弯曲物体的物理学、材料科学和化学,包括二维材料、复杂氧化物、半金属、多铁、天磁、反铁磁体、挫折磁体、磁性分子/纳米粒子、离子导体、超导体、自旋电子和自旋轨道材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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