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Angle-resolved Transport and Nonlinear Hall Effect in Bernal Bilayer Graphene

Offered By: International Centre for Theoretical Sciences via YouTube

Tags

Quantum Materials Courses Condensed Matter Physics Courses Two-dimensional Materials Courses

Course Description

Overview

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Explore angle-resolved transport and nonlinear Hall effect in Bernal bilayer graphene in this 42-minute lecture by Jia Li from the International Centre for Theoretical Sciences. Part of the "Engineered 2D Quantum Materials" program, this talk delves into emergent electronic, magnetic, and topological phenomena in two-dimensional synthetic structures of quantum materials. Gain insights into the interplay between electronic correlations, spin-orbit coupling, crystal structure, symmetry, and topology in reduced dimensionality systems. Learn about frustrated coupling across 2D interfaces and enhanced interlayer interactions leading to new electronic band structures and emergent behaviors. Suitable for physicists and materials scientists interested in artificially engineered heterostructures, this lecture contributes to a broader discussion on topics such as magnetism, topological superconductivity, flat bands, correlated phenomena, and quantum simulators in engineered 2D materials.

Syllabus

Angle-resolved Transport and Nonlinear Hall effect in Bernal Bilayer Graphene by Jia Li


Taught by

International Centre for Theoretical Sciences

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