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Title
Glide-symmetric Z2 magnetic topological crystalline insulators / Heejae Kim.
ISBN
9789811690778 (electronic bk.)
9811690774 (electronic bk.)
9811690766
9789811690761
Publication Details
Singapore : Springer, 2022.
Language
English
Description
1 online resource
Item Number
10.1007/978-981-16-9077-8 doi
Call Number
TK7872.T57
Dewey Decimal Classification
621.319/37
Summary
This book presents a comprehensive theory on glide-symmetric topological crystalline insulators. Beginning with developing a theory of topological phase transitions between a topological and trivial phase, it derives a formula for topological invariance in a glide-symmetric topological phase when inversion symmetry is added into a system. It also shows that the addition of inversion symmetry drastically simplifies the formula, providing insights into this topological phase, and proposes potential implementations. Lastly, based on the above results, the author establishes a way to design topological photonic crystals. Allowing readers to gain a comprehensive understanding of the glide-symmetric topological crystalline insulators, the book offers a way to produce such a topological phase in various physical systems, such as electronic and photonic systems, in the future.
Note
"Doctoral thesis accepted by Tokyo Institute of Technology, Tokyo, Japan."
Bibliography, etc. Note
Includes bibliographical references.
Access Note
Access limited to authorized users.
Source of Description
Online resource; title from PDF title page (SpringerLink, viewed February 4, 2022).
Series
Springer theses, 2190-5061
Available in Other Form
Print version: 9789811690761
Introduction
Topology, Symmetry, and Band Theory of Materials
Weyl Semimetals and Spinless Z2 Magnetic Topological Crystalline Insulators with Glide Symmetry
Interplay of Glide-Symmetric Z2 Magnetic Topological Crystalline Insulators And Symmetry: Inversion Symmetry And Nonprimitive Lattice
Topological Invariants And Tight-Binding Models From The Layer Constructions
Conclusion and Outlook.