Imaging magnetic order in a two-dimensional iron-rich phyllosilicate

Muhammad Zubair Khan; Andriani Vervelaki; Daniel Jetter; Kousik Bagani; Andreas Ney; Oleg Peil; Sergio Valencia; Alevtina Smekhova; Florian Kronast; Daniel  Knez; Martina Dienstleder; Martino Poggio; Aleksandar Matkovic

doi:10.1038/s43246-025-00936-7

Imaging magnetic order in a two-dimensional iron-rich phyllosilicate

Muhammad Zubair Khan
, Andriani Vervelaki
, Daniel Jetter
, Kousik Bagani
, Andreas Ney
, Oleg Peil
, Sergio Valencia
, Alevtina Smekhova
, Florian Kronast
, Daniel Knez
, Martina Dienstleder
, Martino Poggio
, Aleksandar Matkovic

Chair of Physics (460)

Research output: Contribution to journal › Article › Research › peer-review

Abstract

Magnetic domain formation in two-dimensional materials offers insight into the fundamentals of magnetism and serves as a catalyst for the advancement of spintronics. In order to propel these developments, it is crucial to acquire an understanding of the evolution of magnetic ordering at the nanometer scale. In particular, two-dimensional magnetic insulators allow for the realization of atomically sharp magnetoresistive tunneling junctions with nonmagnetic electrodes, therefore lifting one of the major constraints for the realization of computing in memory based on magnetoresistive elements. In this study, we visualize magnetic ordering in monolayers of annite, a fully air-stable layered magnetic mica. Using a nanometer-scale scanning superconducting quantum interference device microscopy, we directly observe domain formation in this representative of two-dimensional magnetic phyllosilicates.

Original language	English
Article number	217
Number of pages	8
Journal	Communications materials
Volume	2025
Issue number	6
DOIs	https://doi.org/10.1038/s43246-025-00936-7
Publication status	Published - 2 Oct 2025

Keywords

annite
2D insulators
2D magnetism
squid microscopy
SQUID

Access to Document

10.1038/s43246-025-00936-7Licence: CC BY

Cite this

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title = "Imaging magnetic order in a two-dimensional iron-rich phyllosilicate",

abstract = "Magnetic domain formation in two-dimensional materials offers insight into the fundamentals of magnetism and serves as a catalyst for the advancement of spintronics. In order to propel these developments, it is crucial to acquire an understanding of the evolution of magnetic ordering at the nanometer scale. In particular, two-dimensional magnetic insulators allow for the realization of atomically sharp magnetoresistive tunneling junctions with nonmagnetic electrodes, therefore lifting one of the major constraints for the realization of computing in memory based on magnetoresistive elements. In this study, we visualize magnetic ordering in monolayers of annite, a fully air-stable layered magnetic mica. Using a nanometer-scale scanning superconducting quantum interference device microscopy, we directly observe domain formation in this representative of two-dimensional magnetic phyllosilicates.",

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T1 - Imaging magnetic order in a two-dimensional iron-rich phyllosilicate

AU - Khan, Muhammad Zubair

AU - Vervelaki, Andriani

AU - Jetter, Daniel

AU - Bagani, Kousik

AU - Ney, Andreas

AU - Peil, Oleg

AU - Valencia, Sergio

AU - Smekhova, Alevtina

AU - Kronast, Florian

AU - Knez, Daniel

AU - Dienstleder, Martina

AU - Poggio, Martino

AU - Matkovic, Aleksandar

PY - 2025/10/2

Y1 - 2025/10/2

N2 - Magnetic domain formation in two-dimensional materials offers insight into the fundamentals of magnetism and serves as a catalyst for the advancement of spintronics. In order to propel these developments, it is crucial to acquire an understanding of the evolution of magnetic ordering at the nanometer scale. In particular, two-dimensional magnetic insulators allow for the realization of atomically sharp magnetoresistive tunneling junctions with nonmagnetic electrodes, therefore lifting one of the major constraints for the realization of computing in memory based on magnetoresistive elements. In this study, we visualize magnetic ordering in monolayers of annite, a fully air-stable layered magnetic mica. Using a nanometer-scale scanning superconducting quantum interference device microscopy, we directly observe domain formation in this representative of two-dimensional magnetic phyllosilicates.

AB - Magnetic domain formation in two-dimensional materials offers insight into the fundamentals of magnetism and serves as a catalyst for the advancement of spintronics. In order to propel these developments, it is crucial to acquire an understanding of the evolution of magnetic ordering at the nanometer scale. In particular, two-dimensional magnetic insulators allow for the realization of atomically sharp magnetoresistive tunneling junctions with nonmagnetic electrodes, therefore lifting one of the major constraints for the realization of computing in memory based on magnetoresistive elements. In this study, we visualize magnetic ordering in monolayers of annite, a fully air-stable layered magnetic mica. Using a nanometer-scale scanning superconducting quantum interference device microscopy, we directly observe domain formation in this representative of two-dimensional magnetic phyllosilicates.

KW - annite

KW - 2D insulators

KW - 2D magnetism

KW - squid microscopy

KW - SQUID

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