Exploration of Quantum Transport Phenomena via Engineering Emergent Magnetic Fields in Topological Magnets, 1st ed. 2021
Springer Theses Series

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Language: English

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Exploration of Quantum Transport Phenomena via Engineering Emergent Magnetic Fields in Topological Magnets
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92 p. · 15.5x23.5 cm · Paperback

158.24 €

In Print (Delivery period: 15 days).

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Exploration of Quantum Transport Phenomena via Engineering Emergent Magnetic Fields in Topological Magnets
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This book addresses novel electronic and thermoelectronic properties arising from topological spin textures as well as topologically non-trivial electronic structures. In particular, it focuses on a unique topological spin texture, i.e., spin hedgehog lattice, emerging in a chiral magnet and explore its novel properties which are distinct from the conventional skyrmion lattice, and discusses the possibility of realizing high-temperature quantum anomalous Hall effect through quantum confinement effect in topological semimetal. This book benefits students and researchers working in the field of condensed matter physics, through providing comprehensive understanding of the current status and the outlook in the field of topological magnets.

Introduction.- Experimental Methods.- Topological Transitions Between Skyrmion- and Hedgehog-lattice States in MnSi1-xGex.- Giant magneto-transport properties induced by spin fluctuations in MnGe.- Topological Transport Properties of Weyl Semimetal/Dirac Metal in Kagome Magnets.- Summary.- Appendix.
Dr. Yukako Fujishiro is a postdoctoral researcher at the RIKEN Center for Emergent Matter Science in Japan. She received her PhD in applied physics from the University of Tokyo in 2021. Her current work focuses on the exploration of new materials, which have topologically non-trivial electronic or magnetic structures, as well as their potential functions and applications.

Nominated as an outstanding Ph.D. thesis by the University of Tokyo, Japan

Highlights unique properties of skyrmion and hedgehog lattice state

Provides novel approach toward high-temperature quantum anomalous Hall effect through quantum confinement effect