Broken symmetry states and Quantum Hall Ferromagnetism in decoupled twisted bilayer graphene

Abstract: Twisted bilayer graphene (TBLG) with large twist angle is a novel 2D bilayer system with strong interlayer Coulomb interactions, whilst suppressed interlayer carrier tunneling due to momentum mismatch between the Dirac cones of individual graphene layers. This interlayer decoherence disentangles the layer degree of freedom from spin-valley space. We demonstrate the role of charge screening effects in electronically decoupled TBLG that determines the Landau level (LL) crossings and multicomponent Quantum Hall (QH) effect resulting from combinations of broken symmetry states with spin and valley flavors of constituent layers.The N = 0 LL at zero filling factor is characterized by a field-induced Kosterlitz-Thouless transition to an ordered ground state, consistent with predictions of intervalley coherent state of Kekul\'e order. Pronounced hysteresis and electron-hole asymmetry observed in the QH regime suggests pinning of low-energy topological excitations, i.e., skyrmions with spin and valley textures, at charged defects in graphene channel.