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Paper detail

Strain-driven domain wall network with chiral junctions in an antiferromagnet

Materials with antiferromagnetic order have recently emerged as promising candidates in spintronics based on their beneficial characteristics such as vanishing stray fields and ultra-fast dynamics. At the same time more complex localized non-coplanar magnetic states as for instance skyrmions are in the focus of applications due to their intriguing properties such as the topological Hall effect. Recently a conceptual shift has occurred to envision the use of such magnetic defects not only in one-dimensional race track devices but to exploit their unique properties in two-dimensional networks. Here we use local strain in a collinear antiferromagnet to induce non-coplanar domain wall junctions, which connect in a very specific way to form extended networks. We combine spin-polarized scanning tunneling microscopy with density functional theory to characterize the different building blocks of the network, and unravel the origin of the handedness of triple-junctions and the size of the arising topological orbital moments.

preprint2024arXivOpen access
Vishesh SaxenaMara GutzeitArturo Rodríguez-SotaSoumyajyoti HaldarFelix ZahnerRoland WiesendangerAndré KubetzkaStefan HeinzeKirsten von Bergmann
cond-mat.mes-hallcond-mat.mtrl-sci
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Vishesh SaxenaMara GutzeitArturo Rodríguez-SotaSoumyajyoti HaldarFelix ZahnerRoland WiesendangerAndré KubetzkaStefan HeinzeKirsten von Bergmann

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