The transformation of digital computers from bulky machines to portable systems has been
enabled by new materials and advanced processing technologies that allow ultrahigh …

Quantum information science and engineering (QISE)—which entails the use of quantum
mechanical states for information processing, communications, and sensing—and the area …

Graphene quantum dots (GQDs) not only have potential applications on spin qubit, but also
serve as essential platforms to study the fundamental properties of Dirac fermions, such as …

Carbon materials secure to progress a plenty of real-world technologies. In particular, they
are emerging materials in numerous electrochemical applications, including electrochemical …

Bilayer graphene is a promising platform for electrically controllable qubits in a two-
dimensional material. Of particular interest is the ability to encode quantum information in …

Electron and hole Bloch states in bilayer graphene exhibit topological orbital magnetic
moments with opposite signs, which allows for tunable valley-polarization in an out-of-plane …

The theory of the orbital Hall effect (OHE), a transverse flow of orbital angular momentum
(OAM) in response to an electric field, has concentrated on intrinsic mechanisms. Here …

The Kondo effect is a cornerstone in the study of strongly correlated fermions. The coherent
exchange coupling of conduction electrons to local magnetic moments gives rise to a Kondo …

Particle–hole symmetry plays an important role in the characterization of topological phases
in solid-state systems. It is found, for example, in free-fermion systems at half filling and it is …

Quantum states in graphene are 2-fold degenerate in spins, and 2-fold in valleys. Both
degrees of freedom can be utilized for qubit preparations. In our bilayer graphene quantum …