An accurate technique leveraging conservative higher-order time stepping is proposed to analyze electrostatically induced waveguides in graphene. These highly tunable one-dimensional (1D) electronic channels are a promising interconnect alternative for graphene nanoribbons (GNRs) and carbon nanotubes (CNTs) to be used in future integrated circuits (ICs). A detailed discussion of the eigenmodes of these waveguides is presented and specific attention is paid to the orthogonality relations, which are remarkably similar to their electromagnetic counterpart. Furthermore, it is demonstrated that the addition of a vector potential does not affect the long-term properties of the time stepping scheme. To showcase the accuracy and applicability of the constructed technique two practical electronic waveguide devices are simulated: a dot resonator and a 50/50 splitter containing no bends. The dot resonator exhibits frequency selective behavior that proves to be tunable by both the scalar and vector potential, while the desired output characteristic is obtained for the splitter after carefully tuning the confining potentials.
Conservative fourth-order accurate finite-difference scheme to solve the (3+1)D tilted Dirac equation in strained Dirac semimetals
Owing to their increased electron mobility compared to conventional semiconductors, three-dimensional (3D) Dirac semimetals are considered to be promising candidates for integration into next-generation electronic