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Imaging Quantum Oscillations in Strongly Correlated Moire Systems

Offered By: Kavli Institute for Theoretical Physics via YouTube

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Strongly Correlated Systems Courses Topology Courses Condensed Matter Physics Courses Superconductivity Courses Twisted Bilayer Graphene Courses Moire Materials Courses Quantum Matter Courses

Course Description

Overview

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Explore a 46-minute conference talk on imaging quantum oscillations in strongly correlated moiré systems, presented by Eli Zeldov from the Weizmann Institute. Recorded as part of the "Moiré materials: A New Paradigm in Tunable Quantum Matter" conference at the Kavli Institute for Theoretical Physics (KITP), delve into the fascinating world of moiré materials and their unprecedented tunability for band structure, symmetry, and topology. Gain insights into pressing theoretical questions surrounding these materials, including the origin of superconductivity, the nature of correlated states, and the role of topology. Learn about experimental challenges, novel techniques, and emerging tunable platforms such as twisted superconductors, topological surface states, quasi-periodic moiré systems, and twisted magnetic materials. Discover how this unified approach creates a rich platform for investigating various phenomena in quantum matter.

Syllabus

Imaging quantum oscillations in strongly correlated moire systems ▸ Eli Zeldov (Weizmann Inst.)


Taught by

Kavli Institute for Theoretical Physics

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