We have achieved a multitude of seminal scientific results in the general investigation of magic angle twisted bilayer graphene, where we have discovered many new electronic phases, and also have shown novel control knobs for quantum phases in these systems.
In particular we have observed clear topological Chern insulator phases in this system, which is summarized in a series of papers "Symmetry-broken Chern insulators and Rashba-like Landau-level crossings in magic-angle bilayer graphene" (Nature Physics volume 17, pages710–714 (2021)), "Twisted bilayer graphene. IV. Exact insulator ground states and phase diagram" (Physical Review B, 103, 205414 (2021)), "Competing Zero-Field Chern Insulators in Superconducting Twisted Bilayer Graphene" (Phys. Rev. Lett. 127, 197701 (2021)), "Chern mosaic and Berry-curvature magnetism in magic-angle graphene" (Nature Physics volume 18, pages885–892 (2022)).
We have further investigated magic angle graphene devices in ultra-high magnetic fields, where we have observed re-entrant correlated insulating phases at one magnetic flux through the moire unit cell " Observation of re-entrant correlated insulators and interaction driven Fermi surface reconstructions at one magnetic flux quantum per moiré unit cell in magic-angle twisted bilayer graphene" (Physical Review Letters, 128, 217701 (2022)), "Reentrant correlated insulators in twisted bilayer graphene at 25T (2π flux)" (Physical Review Letters, 129, 076401 (2022)).
We have show that superconductivity in twisted bilayer graphene originates from a non-Fermi liquid like metallic state, in analogy to a strange metal state "Quantum-critical behavior in magic-angle twisted bilayer graphene" (Nature Physics, 18, 633 (2022)).
We have constructed gate defined Josephson junctions from magic angle graphene devices, where we have demonstrated their symmetry broken ground states "Symmetry Broken Josephson Junctions and Superconducting Diodes in Magic Angle Twisted Bilayer Graphene" (Nature Communications, 14, 2396 (2023)), "φ0-Josephson junction in twisted bilayer graphene induced by a valley-polarized state" (Physical Review Research, 5, 023029 (2023)).
We have investigate the thermal conductivity of the electrons in the superconducting state in magic angle graphene, where we have demonstrated its power law dependence, which could be consistent with a nodal superconducting gap structure "Revealing the thermal properties of superconducting magic-angle twisted bilayer graphene" (Nano Letters, 22, 6465 (2022)).
We have further constructed a new type of magic angle trilayer graphene system, which show similar superconducting and correlated phases as magic angle bilayer graphene. In this system we were able to show a new method to measure the correlated gaps in the system "Dirac spectroscopy and strongly correlated phases in twisted trilayer graphene" (Nature Materials, 22, 336 (2023)).