Magnetic Band Gap Opening in Long Sequences of Rhombohedral-stacked Multilayer Graphene

Attempts to induce a clean and stabilized gap in the excitation spectrum of graphene, or a robust magnetism preserving a high carrier mobility have not been successful yet. An alternative procedure to achieve an optical gap and a magnetic state in graphene is to explore correlated states in flat electronic bands hosted by multilayer graphene with rhombohedral stacking. The low kinetic energy of such carriers could lead to gap opening even at weak Coulomb repulsion by stabilizing a magnetic or superconducting state. Here, we directly image the band structure of large graphitic flake containing approximately 14 consecutive ABC layers. We reveal the flat electronic bands and identify a gapped magnetic state by comparing angle-resolved photoemission spectroscopy with first-principle calculations. The gap is robust and stable at liquid nitrogen temperature. Our work opens up new perspectives in the development of optoelectronic and spintronic devices made of easily processable carbon materials.