Explore the Pomeranchuk effect and entropy of fluctuating ferromagnets in twisted bilayer graphene in this 41-minute conference talk by Andrea Young from the Kavli Institute for Theoretical Physics. Delve into topics such as superconductivity, linear T resistivity, magnetism, electronic energy gaps, and magnetic imaging. Examine orbital magnets, orbital churn insulators, and the effects of in-plane magnetic fields. Investigate order by disorder, implications for superconductivity, and symmetry breaking. Analyze the Hall effect, hull density, non-uniform magnetization, and local moment variation. Gain insights into the latest developments in Moire materials physics, presented as part of the "Correlated Phases in Moire Materials: One Year Later" online reunion conference.
Pomeranchuk Effect and the Entropy of Fluctuating Ferromagnets in Twisted Bilayer
Kavli Institute for Theoretical Physics via YouTube
Overview
Syllabus
Introduction
Superconductivity
Linear T resistivity
Magnetism
Electronic energy gap
Magnetic imaging
Magnetic moment
Orbital magnets
Orbital churn insulators
Inplane magnetic field
Order by disorder
What does this mean
What does this mean for superconductivity
Where does this symmetry breaking happen
Hall effect and hull density
Nonuniform magnetization
Alignment and coupling
Local moment variation
Raoul Fernandez
Taught by
Kavli Institute for Theoretical Physics
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