Flat-band systems with strongly correlated electrons can exhibit a variety of phenomena,
such as correlated insulating and topological states, unconventional superconductivity, and …

ABC-stacked multilayer graphene (ABC-MLG) exhibits topological surface flat bands with a
divergent density of states, leading to many-body instabilities at charge neutrality. Here, we …

The recent discovery of superconductivity and magnetism in trilayer rhombohedral graphene
(RG) establishes an ideal, untwisted platform to study strong correlation electronic …

In spite of 40 years of experimental studies and several theoretical proposals, an overall
interpretation of the complex behavior of the magnetoresistance (MR) of multilayer …

Strongly correlated states commonly emerge in twisted bilayer graphene (TBG) with “magic-
angle”(1.1°), where the electron–electron (ee) interaction U becomes prominent relative to …

We model the electronic properties of thin films of binary compounds with stacked layers
where each layer is a two-dimensional honeycomb lattice with two atoms per unit cell. The …

We model the influence of an in-plane magnetic field on the orbital motion of electrons in
rhombohedral graphene multilayers. For zero field, the low-energy band structure includes a …

Nodal loop semimetals are topological materials with drumhead surface states
characterized by reduced kinetic energy. If the Fermi energy of such a system is near these …

Rhombohedral (ABC) stacked multilayer graphene hosts low-energy flat bands, which have
proven to be an ideal platform toward achieving interaction-driven physics including …

We study interaction-mediated magnetism on the surface of ABC-multilayer graphene driven
by its zero-energy topological flat bands. Using the random-phase approximation, we treat …