# Sensing Noncollinear Magnetism at the Atomic Scale Combining Magnetic   Exchange and Spin-Polarized Imaging

**Authors:** Nadine Hauptmann, Jan W. Gerritsen, Daniel Wegner, Alexander A., Khajetoorians

arXiv: 1703.06059 · 2017-08-16

## TL;DR

This paper introduces a novel combined magnetic imaging technique that detects spin-polarization and exchange forces at the atomic scale, enabling detailed study of non-collinear magnetic structures like nano-skyrmions.

## Contribution

The study presents a new method combining scanning tunneling microscopy and atomic force microscopy to image non-collinear magnetism at the atomic level, demonstrating its effectiveness on nano-skyrmion lattices.

## Key findings

- Successfully visualized non-collinear magnetic structures at atomic resolution.
- Quantified exchange forces and distinguished their signs using distance-dependent spectroscopy.
- Showed potential for non-perturbative readout and writing of atomic-scale magnetic states.

## Abstract

Storing and accessing information in atomic-scale magnets requires magnetic imaging techniques with single-atom resolution. Here, we show simultaneous detection of the spin-polarization and exchange force, with or without the flow of current, with a new method, which combines scanning tunneling microscopy and non-contact atomic force microscopy. To demonstrate the application of this new method, we characterize the prototypical nano-skyrmion lattice formed on a monolayer of Fe/Ir(111). We resolve the square magnetic lattice by employing magnetic exchange force microscopy, demonstrating its applicability to non-collinear magnetic structures, for the first time. Utilizing distance-dependent force and current spectroscopy, we quantify the exchange forces in comparison to the spin-polarization. For strongly spin-polarized tips, we distinguish different signs of the exchange force which we suggest arises from a change in exchange mechanisms between the probe and a skyrmion. This new approach may enable both non-perturbative readout combined with writing by current-driven reversal of atomic-scale magnets.

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Source: https://tomesphere.com/paper/1703.06059