Magneto-conductance fingerprints of purely quantum states in the open quantum dot limit

Mendoza, Michel; Ujevic, Sebastian

doi:10.1088/0953-8984/24/23/235302

Cited by 9 publications

(11 citation statements)

References 50 publications

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“…Also, this pattern is analogous to the one found in a conductance map (as a function of B and E) of a 2DEG quantum box. In a 2DEG quantum box the magnetic field B plays the same role of the quantity V/t considered in this work [47]. The pattern observed in the Fano resonances of figure 6 for B=8T arises from the Figure 5.…”

Section: Detection Of the Sub-lattice Ls: Impurities And Applied Magnmentioning

confidence: 69%

Exclusive sub-lattices for extended and localized states in graphene ribbons: their role in Klein tunneling, disorder and magnetic field effects

2018

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We report the existence of two sub-lattices in metallic graphene nanoribbons that present a decoupled behavior. Each sub-lattice, one for extended states (ES) and another exclusively for localized states (LS), is formed by a combination of A and B graphene sites. In the sub-lattice ES all electronic transport phenomena occur, including the Klein tunneling through an external applied potential barrier. In contrast, the sub-lattice LS does not contribute to the transport of quasi-particles and strongly localized states are induced within the potential barrier region. The sub-lattices ES and LS are detected by analyzing Klein states and totally localized states that were systematically perturbed by the contributions of hyperboloid bands generated by the potential barrier. This is performed by gradually increasing the energy of the applied potential. The existence of both sub-lattices are tested by considering disorder and magnetic field effects in the system. The results indicate that both sublattices behave as if there are decoupled, even at the presence of an external applied barrier and that they can be coupled by applying an external magnetic field.

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Section: Detection Of the Sub-lattice Ls: Impurities And Applied Magnmentioning

confidence: 69%

Exclusive sub-lattices for extended and localized states in graphene ribbons: their role in Klein tunneling, disorder and magnetic field effects

2018

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“…where the self-energies R and L of the contact leads are numerically calculated using the recursive Green function method [27,37,38]. The polarization P of the sub-lattice (A or B, also called pseudo-spin) is calculated according to…”

Section: The Model and Methodsmentioning

confidence: 99%

Optimization of the polarized Klein tunneling currents in a sub-lattice: pseudo-spin filters and latticetronics in graphene ribbons

López¹,

Yaro²,

Champi³

et al. 2014

J. Phys.: Condens. Matter

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We found that with an increase of the potential barrier applied to metallic graphene ribbons, the Klein tunneling current decreases until it is totally destroyed and the pseudo-spin polarization increases until it reaches its maximum value when the current is zero. This inverse relation disfavors the generation of polarized currents in a sub-lattice. In this work we discuss the pseudo-spin control (polarization and inversion) of the Klein tunneling currents, as well as the optimization of these polarized currents in a sub-lattice, using potential barriers in metallic graphene ribbons. Using density of states maps, conductance results, and pseudo-spin polarization information (all of them as a function of the energy V and width of the barrier L), we found (V, L) intervals in which the polarized currents in a given sub-lattice are maximized. We also built parallel and series configurations with these barriers in order to further optimize the polarized currents. A systematic study of these maps and barrier configurations shows that the parallel configurations are good candidates for optimization of the polarized tunneling currents through the sub-lattice. Furthermore, we discuss the possibility of using an electrostatic potential as (i) a pseudo-spin filter or (ii) a pseudo-spin inversion manipulator, i.e. a possible latticetronic of electronic currents through metallic graphene ribbons. The results of this work can be extended to graphene nanostructures.

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“…where E is the energy of the incoming electrons, the selfenergies [34] Σ R (right) and Σ L (left) of the contact leads are numerically calculated using the recursive Green function method [24,25,35], and H defines a central region that does not consider the contact leads Hamiltonians, H R and H L (all assembled via equation ( 1)). Using the above definitions we can write…”

Section: The Model and Methodsmentioning

confidence: 99%

“…For example, in an GaAs heterostructure the resonant tunneling only occurs for specific energies when two potential barriers are applied. For the rest of the energy spectrum the transmission is totally reduced in comparison with the case without barrier [23][24][25]. As far as we know, an enhancement of the transmission through the system due to the application of potential barriers was never reported.…”

Section: Introductionmentioning

confidence: 94%

Recovery of the scattering symmetry looking at the conductance in asymmetric graphene nano-ribbons systems using pseudo-spin filters

López¹,

Ujevic²,

Mendoza³

2019

J. Phys.: Condens. Matter

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In this work we study some applications for pseudo-spin filters. The filters are potential barriers with hyperboloid sub-band contributions that are locally applied over graphene nano-ribbons. These filters modulate the pseudo-spin and the quirality of the wave-function allowing the recovery of the conductance loss due to imperfections, bends, or constrictions (asymmetries) found in the system. The recovery of the conductance is fulfilled by a direct manipulation of the pseudo-spin polarization at both sides of the device by localizing the filters at the system's entrance and exit points. This procedure allows the recovery of the wave-function symmetry at these points with the consequent recovery of the conductance, even when it is zero, regardless of the different internal regions that affect the transmission, i.e. the filters are used as patches for damaged regions. Our results can be extrapolated for spatially asymmetrical potentials generated by electrical (or magnetic) impurities.

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Magneto-conductance fingerprints of purely quantum states in the open quantum dot limit

Cited by 9 publications

References 50 publications

Exclusive sub-lattices for extended and localized states in graphene ribbons: their role in Klein tunneling, disorder and magnetic field effects

Exclusive sub-lattices for extended and localized states in graphene ribbons: their role in Klein tunneling, disorder and magnetic field effects

Optimization of the polarized Klein tunneling currents in a sub-lattice: pseudo-spin filters and latticetronics in graphene ribbons

Recovery of the scattering symmetry looking at the conductance in asymmetric graphene nano-ribbons systems using pseudo-spin filters

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