Topological Hall Effect induced by chiral fluctuations in a Kagome Lattice

Kyle W Fruhling; Alenna M Streeter; Sougata Mardanya; Xiaoping Wang; Priya R Baral; Oksana Zaharko; Igor I Mazin; Sugata Chowdhury; William Ratcliff; Fazel Tafti

Topological Hall Effect induced by chiral fluctuations in a Kagome Lattice

ORAL

Abstract

The Topological Hall effect (THE) is a hallmark of chiral spin interactions in noncollinear magnetic structures. An outstanding question is whether chiral interactions could exist and induce a THE in a material with a collinear structure as predicted theoretically for a fluctuating chiral order. We report the presence of the Topological Hall Effect in the Kagome material ErMn 6 Sn 6 . Using magnetization and neutron scattering data we confirm the presence of a field-induced ferrimagnetic (FiM) to antiferromagnetic (AFM) transition and the collinear magnetic structure of these phases. We then calculate the strength of the THE and show that it is present and strongly anisotropic. A mapping of the magnitude of THE shows it correlates with the boundary of the field-induced phase transition.

^*This work was funded by the National Science Foundation under Award No. DMR-2203512

March 7, 2024, 1:54 PM – March 7, 2024, 2:06 PM

Presenters

Kyle W Fruhling
- Boston College

Authors

Kyle W Fruhling
- Boston College
Alenna M Streeter
- Boston College
Sougata Mardanya
- Howard University
- Howard university
Xiaoping Wang
- Oak Ridge National Laboratory
Priya R Baral
- Paul Scherrer Institut
- Paul Scherrer Institute
Oksana Zaharko
- Paul Scherrer Institut
Igor I Mazin
- George Mason University
- Department of Physics and Astronomy, George Mason University; Quantum Science and Engineering Centre, George Mason University
Sugata Chowdhury
- Howard University
William Ratcliff
- NIST, University of Maryland
- National Institute of Standards and Technology
Fazel Tafti
- Boston College