Topological Magnetism Group

Discovery of an antiferromagnetic topological nodal-line Kondo semimetal

arXiv (2024)

Authors:

Defa F Liu, YF Xu, HY Hu, JY Liu, Yh Yang, D Pei, Dharmalingam Prabhakaran, Thorsten Hesjedal, Yulin Chen

Abstract:

The symbiosis of strong interactions, flat bands, topology and symmetry has led to the discovery of exotic phases of matter, including fractional Chern insulators, correlated moiré topological superconductors, and Dirac and Weyl semimetals. Correlated metals, such as those present in Kondo lattices, rely on the screening of local moments by a sea of non-magnetic conduction electrons. Here, we report on a unique topological Kondo lattice compound, CeCo2P2, where the Kondo effect - whose existence under the magnetic Co phase is protected by PT symmetry - coexists with antiferromagnetic order emerging from the flat bands associated with the Co atoms. Remarkably, this is the only known Kondo lattice compound where magnetic order occurs in non-heavy electrons, and puzzlingly, at a temperature significantly higher than that of the Kondo effect. Furthermore, at low temperatures, the emergence of the Kondo effect, in conjunction with a glide-mirror-z symmetry, results in a nodal line protected by bulk topology near the Fermi energy. These unusual properties, arising from the interplay between itinerant and correlated electrons from different constituent elements, lead to novel quantum phases beyond the celebrated topological Kondo insulators and Weyl Kondo semimetals. CeCo2P2 thus provides an ideal platform for investigating narrow bands, topology, magnetism, and the Kondo effect in strongly correlated electron systems.

Influence of an ultrathin Mn ‘spy layer’ on the static and dynamic magnetic coupling within FePt/NiFe bilayers

Journal of Physics D IOP Publishing 58 (2024) 045002

Authors:

David G Newman, Andreas Frisk, David M Burn, Barat Achinuq, Emily Heppell, Graham J Bowden, Maciej Dabrowski, Gerrit van der Laan, Thorsten Hesjedal, Robert J Hicken

Slow equilibrium relaxation in a chiral magnet mediated by topological defects

Physical Review Letters American Physical Society 133:16 (2024) 166707

Authors:

Chenhao Zhang, Yang Wu, Jingyi Chen, Haonan Jin, Jinghui Wang, Raymond Fan, Paul Steadman, Gerrit van der Laan, Thorsten Hesjedal, Shilei Zhang

Abstract:

We performed a pump-probe experiment on the chiral magnet Cu_{2}OSeO_{3} to study the relaxation dynamics of its noncollinear magnetic orders, employing a millisecond magnetic field pulse as the pump and resonant elastic x-ray scattering as the probe. Our findings reveal that the system requires ∼0.2  s to stabilize after the perturbation applied to both the conical and skyrmion lattice phase, which is significantly slower than the typical nanosecond timescale observed in micromagnetics. This prolonged relaxation is attributed to the formation and slow dissipation of local topological defects, such as emergent monopoles. By unveiling the experimental lifetime of these emergent singularities in a noncollinear magnetic system, our study highlights a universal relaxation mechanism in solitonic textures within the slow dynamics regime, offering new insights into topological physics and advanced information storage solutions.

Slow Equilibrium Relaxation in a Chiral Magnet Mediated by Topological Defects

(2024)

Authors:

Chenhao Zhang, Yang Wu, Jingyi Chen, Haonan Jin, Jinghui Wang, Raymond Fan, Paul Steadman, Gerrit van der Laan, Thorsten Hesjedal, Shilei Zhang

Rolling Motion of Rigid Skyrmion Crystallites Induced by Chiral Lattice Torque.

Nano letters American Chemical Society (ACS) (2024)

Authors:

Haonan Jin, Jingyi Chen, Gerrit van der Laan, Thorsten Hesjedal, Yizhou Liu, Shilei Zhang

Abstract:

Magnetic skyrmions are topologically protected spin textures with emergent particle-like behaviors. Their dynamics under external stimuli is of great interest and importance for topological physics and spintronics applications alike. So far, skyrmions are only found to move linearly in response to a linear drive, following the conventional model treating them as isolated quasiparticles. Here, by performing time and spatially resolved resonant elastic X-ray scattering of the insulating chiral magnet Cu2OSeO3, we show that for finite-sized skyrmion crystallites, a purely linear temperature gradient not only propels the skyrmions but also induces continuous rotational motion through a chiral lattice torque. Consequently, a skyrmion crystallite undergoes a rolling motion under a small gradient, while both the rolling speed and the rotational sense can be controlled. Our findings offer a new degree of freedom for manipulating these quasiparticles toward device applications and underscore the fundamental phase difference between the condensed skyrmion lattice and isolated skyrmions.