Browsing by Author "Bonilla Moreno, Daniel"
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- ItemElectromagnetic coupling and transport in a topological insulator-graphene hetero-structure(2023) Bonilla Moreno, Daniel; Castaño Yepes, J.D.; Martín Ruiz, A.; Muñoz, EnriqueThe electromagnetic coupling between hetero-structures made of different materials is of great interest, both from the perspective of discovering new phenomena, as well as for its potential applications in novel devices. In this work, we study the electromagnetic coupling of a hetero-structure made of a topological insulator (TI) slab and a single graphene layer, where the later presents a diluted concentration of ionized impurities. We explore the topological effects of the magneto-electric polarizability (MEP) of the TI, as well as its relative dielectric permittivity on the electrical conductivity in graphene at low but finite temperatures. Copyright © 2023, The Authors. All rights reserved.
- ItemElectromagnetic coupling and transport in a topological insulator–graphene heterostructure(2023) Bonilla Moreno, Daniel; Castaño Yepes, Jorge David; Martín Ruiz, A.; Muñoz, EnriqueThe electromagnetic coupling between heterostructures made of different materials is of great interest, both from the perspective of discovering new phenomena, as well as for its potential applications in novel devices. In this work, we study the electromagnetic coupling of a heterostructure made of a topological insulator (TI) slab and a single graphene layer, where the later presents a diluted concentration of ionized impurities. We explore the topological effects of the magnetoelectric polarizability of the TI, as well as its relative dielectric permittivity on the electrical conductivity in graphene at low but finite temperatures.
- ItemElectronic Transport in Weyl Semimetals with a Uniform Concentration of Torsional Dislocations(2022) Bonilla Moreno, Daniel; Muñoz, EnriqueIn this article, we consider a theoretical model for a type I Weyl semimetal, under the presence of a diluted uniform concentration of torsional dislocations. By means of a mathematical analysis for partial wave scattering (phase-shift) for the T-matrix, we obtain the corresponding retarded and advanced Green’s functions that include the effects of multiple scattering events with the ensemble of randomly distributed dislocations. Combining this analysis with the Kubo formalism, and including vertex corrections, we calculate the electronic conductivity as a function of temperature and concentration of dislocations. We further evaluate our analytical formulas to predict the electrical conductivity of several transition metal monopnictides, i.e., TaAs, TaP, NbAs, and NbP.
- ItemExact solution of the Schrödinger equation for an hydrogen atom at the interface between the vacuum and a topologically insulating surface(2019) Bonilla Moreno, Daniel; Martín Ruiz, A.; Urrutia, L. F.When an hydrogen atom is brought near to the interface between θ-media, the quantum-mechanical motion of the electron will be affected by the electromagnetic interaction between the atomic charges and the θ-interface, which is described by an axionic extension of Maxwell electrodynamics in the presence of a boundary. In this paper we investigate the atom-surface interaction effects upon the energy levels and wave functions of an hydrogen atom placed at the interface between a θ-medium and the vacuum. In the approximation considered, the Schrödinger equation can be exactly solved by separation of variables in terms of hypergeometic functions for the angular part and hydrogenic functions for the radial part. In order to make such effects apparent we deal with unrealistic high values of the θ-parameter. We also compute the energy shifts using perturbation theory for a particular small value of θ and we demonstrate that they are in a very good agreement with the ones obtained from the exact solution.
- ItemExact solution of the Schrödinger equation for an hydrogen atom at the interface between the vacuum and a topologically insulating surface(2019) Bonilla Moreno, Daniel; Martín Ruiz, Alberto; Urrutia, Luis F.When a hydrogen atom is brought near the interface between θ-media, the quantum-mechanical motion of the electron will be affected by the electromagnetic interaction between the atomic charges and the θ-interface, which is described by an axionic extension of Maxwell electrodynamics in the presence of a boundary. In this paper we investigate the atom-surface interaction effects upon the energy levels and wave functions of a hydrogen atom placed at the interface between a θ-medium and the vacuum. In the approximation considered, the Schr¨odinger equation can be exactly solved by separation of variables in terms of hypergeometic functions for the angular part and hydrogenic functions for the radial part. In order to make such effects apparent we deal with unrealistic high values of the θ-parameter. We also compute the energy shifts using perturbation theory for a particular small value of θ and we demonstrate that they are in very good agreement with the ones obtained from the exact solution.
- ItemQuantum transport across a slab of a type I Weyl Semimetal with a uniform concentration of torsion dislocation defects(2023) Bonilla Moreno, Daniel; Muñoz, EnriqueIn this work, we study the electronic transport in a Type I Weyl Semimetal slab with a uniform and diluted concentration of torsional dislocation defects. The defects have cylindrical geometry and are modeled as a pseudo-gauge field accounting for torsional strain and a repulsive delta-shell potential for the lattice mismatch effect. We give explicit forms for the retarded Green function in the presence of uniformly distributed scattering centers and the spectral density in terms of the relaxation time (imaginary part of the self-energy). The relaxation time is computed from the known scattering cross-section as a function of the phase shifts for the single-defect scattering problem. Finally, we use the Kubo formula to calculate electrical conductivity.
- ItemThermo-Magneto-Electric Transport through a Torsion Dislocation in a Type I Weyl Semimetal(2021) Bonilla Moreno, Daniel; Muñoz, Enrique; Soto Garrido, RodrigoHerein, we study electronic and thermoelectric transport in a type I Weyl semimetal nanojunction, with a torsional dislocation defect, in the presence of an external magnetic field parallel to the dislocation axis. The defect is modeled in a cylindrical geometry, as a combination of a gauge field accounting for torsional strain and a delta-potential barrier for the lattice mismatch effect. In the Landauer formalism, we find that due to the combination of strain and magnetic field, the electric current exhibits chiral valley-polarization, and the conductance displays the signature of Landau levels. We also compute the thermal transport coefficients, where a high thermopower and a large figure of merit are predicted for the junction.