Professor Thorsten Hesjedal FInstP

Critical analysis of proximity-induced magnetism in MnTe/Bi₂Te₃ heterostructures

Physical Review Materials American Physical Society (APS) 6:5 (2022) 53402

Authors:

G Awana, R Fujita, A Frisk, P Chen, Q Yao, Aj Caruana, Cj Kinane, N-J Steinke, S Langridge, P Olalde-Velasco, Ss Dhesi, G van der Laan, Xf Kou, Sl Zhang, T Hesjedal, D Backes

Abstract:

An elegant approach to overcome the intrinsic limitations of magnetically doped topological insulators is to bring a topological insulator in direct contact with a magnetic material. The aspiration is to realize the quantum anomalous Hall effect at high temperatures where the symmetry-breaking magnetic field is provided by a proximity-induced magnetization at the interface. Hence, a detailed understanding of the interfacial magnetism in such heterostructures is crucial, yet its distinction from structural and magnetic background effects is a rather nontrivial task. Here, we combine several magnetic characterization techniques to investigate the magnetic ordering in MnTe/Bi2Te3 heterostructures. A magnetization profile of the layer stack is obtained using depth-sensitive polarized neutron reflectometry. The magnetic constituents are characterized in more detail using element-sensitive magnetic x-ray spectroscopy. Magnetotransport measurements provide additional information about the magnetic transitions. We find that the supposedly antiferromagnetic MnTe layer does not exhibit an x-ray magnetic linear dichroic signal, raising doubt that it is in its antiferromagnetic state. Instead, Mn seems to penetrate into the surface region of the Bi2Te3 layer. Furthermore, the interface between MnTe and Bi2Te3 is not abrupt, but extending over ∼2.2 nm. These conditions are the likely reason that we do not observe proximity-induced magnetization at the interface. Our findings illustrate the importance of not solely relying on one single technique as proof for proximity-induced magnetism at interfaces. We demonstrate that a holistic, multitechnique approach is essential to gain a more complete picture of the magnetic structure in which the interface is embedded.

Axially bound magnetic skyrmions: glueing topological strings across an interface

Nano Letters American Chemical Society 22:9 (2022) 3737-3743

Authors:

Kejing Ran, Yizhou Liu, Haonan Jin, Yanyan Shangguan, Yao Guang, Jinsheng Wen, Guoqiang Yu, Gerrit van der Laan, Thorsten Hesjedal, Shilei Zhang

Abstract:

A major challenge in topological magnetism lies in the three-dimensional (3D) exploration of their magnetic textures. A recent focus has been the question of how 2D skyrmion sheets vertically stack to form distinct types of 3D topological strings. Being able to manipulate the vertical coupling should therefore provide a route to the engineering of topological states. Here, we present a new type of axially bound magnetic skyrmion string state in which the strings in two distinct materials are glued together across their interface. Using quasi-tomographic resonant elastic x-ray scattering, the 3D skyrmion profiles before and after their binding across the interface were unambiguously determined and compared. Their attractive binding is accompanied by repulsive twisting, i.e., the coupled skyrmions mutually affect each other via a compensating twisting. This state exists in chiral magnet-magnetic thin film heterostructures, providing a new arena for the engineering of 3D topological phases.

Robust kagome electronic structure in the topological quantum magnets XMn6Sn6 (X=Dy,Tb,Gd, Y)

Physical Review B 105:15 (2022)

Authors:

X Gu, C Chen, WS Wei, LL Gao, JY Liu, X Du, D Pei, JS Zhou, RZ Xu, ZX Yin, WX Zhao, YD Li, C Jozwiak, A Bostwick, E Rotenberg, D Backes, LSI Veiga, S Dhesi, T Hesjedal, G Van Der Laan, HF Du, WJ Jiang, YP Qi, G Li, WJ Shi, ZK Liu, YL Chen, LX Yang

Abstract:

Crystal geometry can greatly influence the emergent properties of quantum materials. As an example, the kagome lattice is an ideal platform to study the rich interplay between topology, magnetism, and electronic correlation. In this work, combining high-resolution angle-resolved photoemission spectroscopy and ab initio calculation, we systematically investigate the electronic structure of XMn6Sn6 (X=Dy,Tb,Gd,Y) family compounds. We observe the Dirac fermion and the flat band arising from the magnetic kagome lattice of Mn atoms. Interestingly, the flat band locates in the same energy region in all compounds studied, regardless of their different magnetic ground states and 4f electronic configurations. These observations suggest a robust Mn magnetic kagome lattice across the XMn6Sn6 family, thus providing an ideal platform for the search for, and investigation of, new emergent phenomena in magnetic topological materials.

Robust Kagome Electronic Structure in Topological Quantum Magnets XMn6Sn6 (X = Dy, Tb, Gd, Y)

(2022)

Authors:

X Gu, C Chen, WS Wei, JY Liu, X Du, D Pei, JS Zhou, RZ Xu, ZX Yin, WX Zhao, YD Li, C Jozwiak, A Bostwick, E Rotenberg, D Backes, LSI Veiga, S Dhesi, T Hesjedal, G van der Laan, HF Du, WJ Jiang, YP Qi, G Li, WJ Shi, ZK Liu, YL Chen, LX Yang

Topological Dirac semi-metals as novel, optically-switchable, helicity-dependent terahertz sources

2022 47TH INTERNATIONAL CONFERENCE ON INFRARED, MILLIMETER AND TERAHERTZ WAVES (IRMMW-THZ 2022) 2022-August (2022)

Authors:

Jessica L Boland, Chelsea Q Xia, Djamshid A Damry, Piet Schonherr, Dharmalingam Prabhakaran, Laura M Herz, Thorsten Hesjedal, Michael B Johnston

Abstract:

The generation and control of terahertz pulses is vital for realizing the potential of terahertz radiation in several sectors, including 6G communication, security and imaging. In this work, we present the topological Dirac semimetal cadmium arsenide as a novel helicity-dependent terahertz source. We show both broadband (single-cycle) and narrowband (multi-cycle) terahertz pulses upon near-infrared photoexcitation at oblique incidence. By varying the incident angle of the photoexcitation pulse, control of the emission frequency can also be achieved, providing a candidate for a tuneable narrowband terahertz source.