Coexistence of ultraheavy and ultrarelativistic Dirac quasiparticles in sandwiched trilayer graphene.

Electrons in quantum materials exhibiting coexistence of flat bands piercing dispersive bands can give rise to strongly correlated phenomena, and are associated with unconventional superconductivity. It is known that in twisted trilayer graphene steep Dirac cones can coexist with band flattening, but the phenomenon is not stable under layer misalignments. Here we show that such a twisted sandwiched graphene (TSWG) - a three-layer van der Waals heterostructure with a twisted middle layer - can have very stable flat bands coexisting with Dirac cones near the Fermi energy when twisted to 1.5 degrees. These flat bands require a specific high-symmetry stacking order, and our atomistic calculations predict that TSWG always relaxes to it. Additionally, with external fields, we can control the relative energy offset between the Dirac cone vertex and the flat bands. Our work establishes TSWG as a new platform for research into strongly interacting phases, and topological transport beyond Dirac and Weyl semimetals.