Data for: Visualizing isospin magnetic texture and intervalley exchange interaction in rhombohedral tetralayer graphene

Multilayer rhombohedral graphene offers a rich platform for strong electron interactions without a moire superlattice. The in situ tunable band structure and nontrivial topology lead to a variety of novel correlated electronic states with isospin order dictated by the interplay of spin-orbit coupling and Hunds exchange interactions. However, versatile methods for mapping local isospin textures and determining the exchange energies are currently lacking. Utilizing a nanoscale superconducting quantum interference device in a vector magnetic field, we image the magnetization textures in tetralayer rhombohedral graphene. We reveal sharp magnetic phase transitions marking spontaneous time reversal symmetry breaking. In the quarter metal phase, the spin and orbital moments align closely, providing a bound on the spin-orbit coupling energy. The half metal phase is shown to have a very small magnetic anisotropy, providing the first experimental lower bound on the intervalley Hunds exchange interaction energy, which is found to be close to its theoretical upper bound. By contrasting to magnetotransport measurements, we show that high-field electronic states are governed by unique topological magnetic band reconstruction. The ability to resolve the local isospin texture and the different interaction energies, paves the way to a better understanding of the phase transition hierarchy and the numerous correlated electronic states arising from spontaneous and induced isospin symmetry breaking in graphene heterostructures.

Journal - Nature Physics