Tuning a resonance in Fock space: Optimization of phonon emission in a resonant-tunneling device

Torres, Luis E. F. Foa; Pastawski, Horacio M.; Makler, S. S.

doi:10.1103/physrevb.64.193304

Cited by 34 publications

(35 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The Hamiltonian parameters are roughly representative of a double-well resonant tunneling devices where electron-phonon interactions manifest as a satellite peak in the conductance. [55] There E 0 = −1.5 eV, V R = V L = −0.1 eV, ω 0 = 0.2 eV and V g ≃ −0.1 eV. We discriminate among different vertical processes contributing to the total transmittance.…”

Section: Application: Decoherence In a Model For A Sasermentioning

confidence: 99%

See 1 more Smart Citation

Generalized multi-terminal decoherent transport: recursive algorithms and applications to SASER and giant magnetoresistance

Cattena

Fernández-Alcázar

Bustos-Marún

et al. 2014

J. Phys.: Condens. Matter

View full text Add to dashboard Cite

Decoherent transport in mesoscopic and nanoscopic systems can be formulated in terms of the D'Amato-Pastawski (DP) model. This generalizes the Landauer-Büttiker picture by considering a distribution of local decoherent processes. However, its generalization for multi-terminal setups is lacking. We first review the original two-terminal DP model for decoherent transport. Then, we extend it to a matrix formulation capable of dealing with multi-terminal problems. We also introduce recursive algorithms to evaluate the Green's functions for general banded Hamiltonians as well as local density of states, effective conductances and voltage profiles. We finally illustrate the method by analyzing two problems of current relevance. 1) Assessing the role of decoherence in a model for phonon lasers (SASER). 2) Obtaining the classical limit of Giant Magnetoresistance from a spin-dependent Hamiltonian. The presented methods should pave the way for computationally demanding calculations of transport through nanodevices, bridging the gap between fully coherent quantum schemes and semiclassical ones.

show abstract

Section: Application: Decoherence In a Model For A Sasermentioning

confidence: 99%

“…It manifests as a satellite peak in the I-V curve. This mechanism led to one [55] of the various proposals for a phonon laser (SASER). [56] In such proposal, a substantial part of the electrons contributing to the current emit an optical phonon.…”

Section: Application: Decoherence In a Model For A Sasermentioning

confidence: 99%

Generalized multi-terminal decoherent transport: recursive algorithms and applications to SASER and giant magnetoresistance

Cattena

Fernández-Alcázar

Bustos-Marún

et al. 2014

J. Phys.: Condens. Matter

View full text Add to dashboard Cite

show abstract

“…The treatment of these models can be distinguished according to the level at which interaction is taken into account. Here, we are in particular interested in two situations in which the many-body problem can be traced back to the dynamics of single electrons on the wire: The first case premises non-interacting electrons for which the current can be computed from a Landauer-like formula [15][16][17][18][19][20]. The second case deals with the opposite limit in which Coulomb repulsion is so strong that at most one excess electron can be located on the molecule.…”

Section: Introductionmentioning

confidence: 99%

Coherent charge transport through molecular wires: Influence of strong Coulomb repulsion

et al. 2006

View full text Add to dashboard Cite

We derive a master equation for the electron transport through molecular wires in the limit of strong Coulomb repulsion. This approach is applied to two typical situations: First, we study transport through an open conduction channel for which we find that the current exhibits an ohmic-like behaviour. Second, we explore the transport properties of a bridged molecular wire, where the current decays exponentially as a function of the wire length. For both situations, we discuss the differences to the case of non-interacting electrons.

show abstract

“…In this way, the many-body electron-phonon interaction problem is mapped into a multi-channel single-electron scattering problem [27,[34][35][36][37][38][39][40].…”

Section: Description Of the Model And Mapping Techniquementioning

confidence: 99%

Spin-dependent shot noise of inelastic transport through molecular quantum dots

Walczak

2006

Journal of Magnetism and Magnetic Materials

View full text Add to dashboard Cite

Here we present a theoretical analysis of the effect of inelastic electron scattering on spin-dependent transport characteristics (conductance, current-voltage dependence, magnetoresistance, shot noise spectrum, Fano factor) for magnetic nanojunction. Such device is composed of molecular quantum dot (with discrete energy levels) connected to ferromagnetic electrodes (treated within the wide-band approximation), where molecular vibrations are modeled as dispersionless phonons. Non-perturbative computational scheme, used in this work, is based on the Green's function theory within the framework of mapping technique (GFT-MT) which transforms the many-body electron-phonon interaction problem into a single-electron multi-channel scattering problem. The consequence of the localized electron-phonon coupling is polaron formation. It is shown that polaron shift and additional peaks in the transmission function completely change the shape of considered transport characteristics.

show abstract

Tuning a resonance in Fock space: Optimization of phonon emission in a resonant-tunneling device

Cited by 34 publications

References 26 publications

Generalized multi-terminal decoherent transport: recursive algorithms and applications to SASER and giant magnetoresistance

Generalized multi-terminal decoherent transport: recursive algorithms and applications to SASER and giant magnetoresistance

Coherent charge transport through molecular wires: Influence of strong Coulomb repulsion

Spin-dependent shot noise of inelastic transport through molecular quantum dots

Contact Info

Product

Resources

About