Magic-Angle Graphene Superlattices - A New Platform for Strongly Correlated Physics

Magic-Angle Graphene Superlattices - A New Platform for Strongly Correlated Physics

APS Physics via YouTube Direct link

Novel Approaches to investigate Strongly Correlated Quantum Materials: ultra-cold atom lattices

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4 of 19

Novel Approaches to investigate Strongly Correlated Quantum Materials: ultra-cold atom lattices

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Magic-Angle Graphene Superlattices - A New Platform for Strongly Correlated Physics

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  1. 1 Acknowledgements
  2. 2 Example Correlated Insulator: Mott Insulators
  3. 3 Mott Insulator: parent compound High-T Cuprate Superconductors
  4. 4 Novel Approaches to investigate Strongly Correlated Quantum Materials: ultra-cold atom lattices
  5. 5 New Platform for Strongly Correlated Physics based on Magic Angle Graphene Superlattices
  6. 6 Welcome to 2D Materials Legoland
  7. 7 Twisted bilayer graphene: twist angle dependence
  8. 8 Magic Angle Twisted Bilayer Graphene (MA-TBG)
  9. 9 Anomalous Insulating Behavior at Half-Filling
  10. 10 Unusual Metal-Insulator Transition
  11. 11 Magnetic Field induced Insulator to Metal Transition both perpendicular and parallel fields!
  12. 12 MA-TBLG Superconducts!!!
  13. 13 Similarity MA-TBLG vs Cuprates
  14. 14 Magnetic field dependence
  15. 15 Phase Coherence Phenomena: Josephson effect & Fraunhofer patterns
  16. 16 Quantum Oscillations & Quasiparticle Fermi Surface
  17. 17 How "Strong" a Superconductor is MA-TBG?
  18. 18 Strong Coupling Superconductivity
  19. 19 New Platform for Strongly Correlated Physics based on Magic Angle (Graphene) Superlattices

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