Electron-phonon interactions in atomically thin topological insulators
As technologies develop rapidly, both energy and environmental crises raise serious concerns. Some special materials, called two-dimensional (2D) topological insulators, can carry electricity without loss only if they are at ultracold temperatures. This study reveals how these insulators start to dissipate energy when they become warmer at room temperature. It also shows how light and matter couple in a magnetic topological insulator, which can help researchers to design new topological switching devices using this topological insulator. Furthermore, this study shows how topological state creates a barrier against superconducting state and how intrinsic superconducting state can be achieved within them.
History
Campus location
AustraliaPrincipal supervisor
Nikhil MedhekarAdditional supervisor 1
David CortieYear of Award
2025Department, School or Centre
Materials Science and EngineeringAdditional Institution or Organisation
ARC Centre of Excellence in Future Low Energy Electronics TechnologiesCourse
Doctor of PhilosophyDegree Type
DoctorateFaculty
Faculty of EngineeringUsage metrics
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Keywords
Main-body physicsMagnetophononic polaritonsElectron-phono interactionsDissipationless energy transportTwo-dimensional topological insulatorsTopological superconductivityMajorana FermionsLattice-dynamicsSpin-phonon couplingTopological switchingLight-matter interactionsTopological phase transitionDipole-dipole interactionsDensity functional perturbation theory (DFPT)Density functional theory (DFT)Spin-orbit couplingSpin physicsQuantum spin Hall effectQuantum anomalous Hall effect
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