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1. Beyond equivalent circuit representations in nonlinear systems with inherent memory

Author

Lopez-Richard, V., Pradhan, S., Silva, R. S. Wengenroth, Lipan, O., Catelano, L. K., Höfling, S., and Hartmann, F.

Subjects
Physics - Applied Physics
Abstract

Basic multimode impedance analysis grounded in the availability of nonequilibrium charge carriers and their retarded path towards equilibrium is used to access the inadequacy of equivalent circuits in nonlinear systems with inherent memory. On the basic grounds of generation and recombination (or trapping) of nonequilibrium carriers and their relaxation times, we show how seeming complexity of frequency-dependent impedance that matches a vast universe of experimental evidences can be reduced to simple combinations of basic microscopic ingredients. Counterintuitive features such as a negative capacitances or unexpected inductances become a metaphoric construction with poor physical meaning, pointing to the limitations and ambiguities of the symbolic nature of "equivalent" circuits. Our approach further provides a microscopic perspective that exposes the linkage of an apparent flux with an apparent inductance dismissing any magnetic essence., Comment: 9 pages, 7 figures

Published
2023
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2. Optical mapping of non-equilibrium charge carriers

Author

Castro, E. David Guarin, Pfenning, A., Hartmann, F., Knebl, G., Teodoro, M. Daldin, Marques, Gilmar E., Höfling, S., Bastard, G., and Lopez-Richard, V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Quantum Physics, 81
Abstract

We investigate the energy relaxation segmentation in a resonant tunneling heterostructures by assessing the optical and transport dynamics of non-equilibrium charge carriers. The electrical and optical properties are analyzed using electronic transport measurements combined with electro- and photoluminescence spectroscopies in continuous-wave mode. The radiative recombination is mainly governed by the creation of heavy holes \textit{via} impact ionization processes. Our results suggest hot electrons and holes populations form independent non-equilibrium systems that do not thermalize among them and with the lattice. Consequently, the carriers effective temperature changes independently at different regions of the heterostructure, with a population distribution for holes colder than for electrons., Comment: This version of the manuscript was submitted to the Journal of the Physical Chemistry C. The revised published version can be found at https://pubs.acs.org/doi/10.1021/acs.jpcc.1c02173

Published
2023
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3. Spin dependent analysis of homogeneous and inhomogeneous exciton decoherence in magnetic fields

Author

Laurindo Jr., V., Castro, E. D. Guarin, Jacobsen, G. M., de Oliveira, E. R. C., Domenegueti, J. F. M., Alén, B., Mazur, Yu. I., Salamo, G. J., Marques, G. E., Marega Jr., E., Teodoro, M. D., and Lopez-Richard, V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter, Physics - Applied Physics
Abstract

This paper discusses the combined effects of optical excitation power, interface roughness, lattice temperature, and applied magnetic fields on the spin-coherence of excitonic states in GaAs/AlGaAs multiple quantum wells. For low optical powers, at lattice temperatures between 4 K and 50 K, the scattering with acoustic phonons and short-range interactions appear as the main decoherence mechanisms. Statistical fluctuations of the band-gap however become also relevant in this regime and we were able to deconvolute them from the decoherence contributions. The circularly polarized magneto-photoluminescence unveils a non-monotonic tuning of the coherence for one of the spin components at low magnetic fields. This effect has been ascribed to the competition between short-range interactions and spin-flip scattering, modulated by the momentum relaxation time.

Published
2021
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4. Determination of carrier density and dynamics via magneto-electroluminescence spectroscopy in resonant tunneling diodes

Author

de Oliveira, E. R. Cardozo, Naranjo, A., Pfenning, A., Lopez-Richard, V., Marques, G. E., Worschech, L., Hartmann, F., Höfling, S., and Teodoro, M. D.

Subjects
Condensed Matter - Materials Science, Physics - Applied Physics
Abstract

We study the magneto-transport and magneto-electroluminescence properties of purely n-doped GaAs/Al$_{0.6}$Ga$_{0.4}$As resonant tunneling diodes with an In$_{0.15}$Ga$_{0.85}$As quantum well and emitter prewell. Before the resonant current condition, magneto-transport measurements reveal charge carrier densities comparable for diodes with and without the emitter prewell. The Landau level splitting is observed in the electroluminescence emission from the emitter prewell, enabling the determination of the charge carrier build-up. Our findings show that magneto-electroluminescence spectroscopy techniques provide useful insights on the charge carrier dynamics in resonant tunneling diodes and is a versatile tool to complement magneto-transport techniques. This approach will drive the way for developing potentially more efficient opto-electronic resonant tunneling devices, by e.g., monitoring voltage dependent charge accumulation for improving built-in fields and hence to maximize photodetector efficiency and/or minimize optical losses., Comment: 9 pages, 7 figures

Published
2020
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5. Anisotropic Confinement, Electronic Coupling and Strain Induced Effects Detected by Valence-Band Anisotropy in Self-Assembled Quantum Dots

Author

Marega E, Liang BL, Mazur Yu, Salamo GJ, Malachias A, Trallero-Giner C, Villegas-Lelovsky L, Teodoro MD, Lopez-Richard V, Calseverino C, and Marques GE

Subjects
Molecular beam epitaxy, Self-assembled quantum dots, Inter-dot coupling, Anisotropic effects, Linear polarized photoluminescence emission, Grazing-incidence X-ray diffraction synchrotron, Optoelectronic, Materials of engineering and construction. Mechanics of materials, TA401-492
Abstract

Abstract A method to determine the effects of the geometry and lateral ordering on the electronic properties of an array of one-dimensional self-assembled quantum dots is discussed. A model that takes into account the valence-band anisotropic effective masses and strain effects must be used to describe the behavior of the photoluminescence emission, proposed as a clean tool for the characterization of dot anisotropy and/or inter-dot coupling. Under special growth conditions, such as substrate temperature and Arsenic background, 1D chains of In0.4Ga0.6 As quantum dots were grown by molecular beam epitaxy. Grazing-incidence X-ray diffraction measurements directly evidence the strong strain anisotropy due to the formation of quantum dot chains, probed by polarization-resolved low-temperature photoluminescence. The results are in fair good agreement with the proposed model.

Published
2011

6. Electroluminescence on-off ratio control of n-i-n GaAs/AlGaAs-based resonant tunneling structures

Author

de Oliveira, E. R. Cardozo, Pfenning, A., Guarin, E. D., Teodoro, M. D., Santos, E. C., Lopez-Richard, V., Marques, G. E., Worschech, L., Hartmann, F., and Höfling, Sven

Subjects
Condensed Matter - Materials Science
Abstract

We explore the nature of the electroluminescence (EL) emission of purely n-doped GaAs/AlGaAs resonant tunneling diodes (RTDs) and the EL evolution with voltage. A singular feature of such a device is unveiled when the electrical output current changes from high to low and the EL on-off ratio is enhanced by 2 orders of magnitude compared to the current on-off ratio. By combining the EL and current properties, we are able to identify two independent impact ionization channels associated with the coherent resonant tunneling current and the incoherent valley current. We also perform the same investigation with an associated series resistance, which induces a bistable electrical output in the system. By simulating a resistance variation for the current-voltage and the EL, we are able to tune the EL on-off ratio by up to 6 orders of magnitude. We further observe that the EL on and off states can be either direct or inverted compared to the tunneling current on and off states. This electroluminescence, combined with the unique RTD properties such as the negative differential resistance (NDR) and high frequency operation, enables the development of high speed functional opto-electronic devices and optical switches., Comment: 6 pages, 6 figures

Published
2018
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7. Electron Scattering in 2D Semiconductors: Contrasting Dirac and Schr\'odinger Behavior

Author

Meneses-Gustin, D., Ulloa, S. E., and Lopez-Richard, V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Electronic transport through a material depends on the response to local perturbations induced by defects or impurities in the material. The scattering processes can be described in terms of phase shifts and corresponding cross sections. The multiorbital nature of the spinor states in transition metal dichalcogenides would naturally suggest the consideration of a massive Dirac equation to describe the problem, while the parabolic dispersion of its conduction and valence bands would invite a simpler Schr\"odinger equation description. Here, we contrast the scattering of massive Dirac particles and Schr\"odinger electrons, in order to assess different asymptotic regimes (low and high Fermi energy) for each one of the electronic models and describe their regime of validity or transition. At low energies, where the dispersion is approximately parabolic, the scattering processes are dominated by low angular momentum channels, which results in nearly isotropic scattering amplitudes. On the other hand, the differential cross section at high Fermi energies exhibits clear signatures of the linear band dispersion, as the partial phase shifts approach a non-zero value. We analyze the electronic dynamics by presenting differential cross sections for both attractive and repulsive scattering centers. The dissimilar behavior between Dirac and Schr\"odinger carriers points to the limits and conditions over which different descriptions are required for the reliable treatment of scattering processes in these materials.

Published
2018
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8. Topology driven g-factor tuning in type-II quantum dots

Author

Llorens, J. M., Lopes-Oliveira, V., López-Richard, V., de Oliveira, E. R. Cardozo, Wevior, L., Ulloa, J. M., Teodoro, M. D., Marques, G. E., García-Cristóbal, A., Quiang-Hai, G., and Alén, B.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We investigate how the voltage control of the exciton lateral dipole moment induces a transition from singly to doubly connected topology in type II InAs/GaAsSb quantum dots. The latter causes visible Aharonov-Bohm oscillations and a change of the exciton g-factor which are modulated by the applied bias. The results are explained in the frame of realistic $\mathbf{k}\cdot\mathbf{p}$ and effective Hamiltonian models and could open a venue for new spin quantum memories beyond the InAs/GaAs realm., Comment: Final Version

Published
2017
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9. Optimal control of hybrid qubits: implementing the quantum permutation algorithm

Author

Rivera-Ruiz, C. M., de Lima, E. F., Fanchini, F. F., Lopez-Richard, V., and Castelano, L. K.

Subjects
Quantum Physics, Condensed Matter - Other Condensed Matter
Abstract

The optimal quantum control theory is employed to determine electric pulses capable of producing quantum gates with high fidelity (higher than 0.9997). Particularly, these quantum gates were chosen to perform the permutation algorithm (Z. Gedik et al., Scientific reports 5, 14671, (2015).) in hybrid qubits in a double quantum dot (DQD) platform. The permutation algorithm is an oracle based quantum algorithm that solves the problem of the permutation parity faster than a classical algorithm without the necessity of entanglement between particles. The only requirement for achieving the speedup is the use of a one-particle quantum system with at least three levels. The high fidelity found in our results is closely related to quantum speed limit, which is a measure of how fast a quantum state can be manipulated. Furthermore, our scheme can be used for the practical realization of different quantum algorithms in DQDs., Comment: 5 pages, 5 figures, comments welcome

Published
2017
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11. Berry phase and Rashba fields in quantum rings in tilted magnetic field

Author

Lopes-Oliveira, V., Castelano, L. K., Marques, G. E., Ulloa, S. E., and Lopez-Richard, V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study the role of different orientations of an applied magnetic field as well as the interplay of structural asymmetries on the characteristics of eigenstates in a quantum ring system. We use a nearly analytical model description of the quantum ring, which allows for a thorough study of elliptical deformations and their influence on the spin content and Berry phase of different quantum states. The diamagnetic shift and Zeeman interaction compete with the Rashba spin-orbit interaction, induced by confinement asymmetries and external electric fields, to change spin textures of the different states. Smooth variations in the Berry phase are observed for symmetric quantum rings as function of applied magnetic fields. Interestingly, we find that asymmetries induce nontrivial Berry phases, suggesting that defects in realistic structures would facilitate the observation of geometric phases.

Published
2015
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12. Exploring the transport properties of polytypic and twin-plane nanowires: from tunneling phase-time to spin-orbit interaction effects

Author

Dias, M. Rebello Sousa, Villegas-Lelovsky, L., Diago-Cisneros, L., Castelano, L. K., Cesar, D. F., Marques, G. E., and Lopez-Richard, V.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The variety of nanowire crystal structures gave rise to unique and novel transport phenomena. In particular, we have explored the superlattice profile generated by strain field modulation in twinplane nanowires for the tuning of transport channels and the built-in spin-orbit potential profile of polytypic nanowires, in order to realize a spin filter. The Multicomponent Scattering Approach has been used in terms of the Transfer Matrix Method to describe the phase-time of charge carriers. This system showed advantages for attaining conditions for the propagation of wave packets with negative group velocity. Moreover, the spin transport effect of a potential profile with volumetric spin-orbit bulk inversion asymmetry, as present on polytypic nanowires, was described through the Reverse Runge-Kutta Method. Using the peculiar symmetry of the excited states we have characterized a dominant spin dependence on structural parameters that results in effective spin filtering., Comment: 17 pages, 7 figures

Published
2015

13. A Memcomputing Pascaline

Author

Pershin, Y. V., Castelano, L. K., Hartmann, F., Lopez-Richard, V., and Di Ventra, M.

Subjects
Computer Science - Emerging Technologies, Condensed Matter - Mesoscale and Nanoscale Physics, Computer Science - Neural and Evolutionary Computing
Abstract

The original Pascaline was a mechanical calculator able to sum and subtract integers. It encodes information in the angles of mechanical wheels and through a set of gears, and aided by gravity, could perform the calculations. Here, we show that such a concept can be realized in electronics using memory elements such as memristive systems. By using memristive emulators we have demonstrated experimentally the memcomputing version of the mechanical Pascaline, capable of processing and storing the numerical results in the multiple levels of each memristive element. Our result is the first experimental demonstration of multidigit arithmetics with multi-level memory devices that further emphasizes the versatility and potential of memristive systems for future massively-parallel high-density computing architectures.

Published
2015
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14. Quantum Dots as an Active Reservoir for Longer Effective Lifetimes in GaAs Bulk.

Author

Jacobsen, G. M., Bragança, H., Mazur, Yu. I., Ware, M. E., Salamo, G. J., Liang, B. L., Marques, G. E., Lopez-Richard, V., and Teodoro, M. D.

Abstract

AlInAs/AlGaAs quantum dots (QDs) have emerged as excellent emitters across the visible spectral range, showcasing highly tunable electronic properties through variations in composition and size. This versatility allows for diverse band alignments within the same system. In this study, we present compelling evidence for the coexistence of type-I indirect and direct emissions from QDs, supported by comprehensive analyses of their photoluminescence responses to excitation power, temperature, and time, along with band structure calculations. The high-density QD system exhibits signs of lateral coupling, facilitated by carrier transfer between dots, modulated by energy barriers and recombination times. Additionally, we can unequivocally prove that the QDs act as carrier reservoirs that progressively feed optically active states in the bulk GaAs at low temperaturesan attractive prospect for hot-carrier photovoltaics. Above certain temperatures, the bulk system reverts to the anticipated predominantly radiative recombination dynamics. Our theoretical framework, accounting for the coexistence of QD specimens with varying recombination times, successfully elucidates the optical response at different temperatures, emphasizing the pivotal role of QD excitation in enhancing the effective lifetime of carriers in the bulk. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Excited states of exciton-polariton condensates in 2D and 1D harmonic traps

Author

Trallero-Giner, C., Durnev, M. V., Fernández, Y. Núñez, Vasilevskiy, M. I., López-Richard, V., and Kavokin, A.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We present a theoretical description of Bogolyubov-type excitations of exciton-polariton Bose-Einstein condensates (BECs) in semiconductor microcavities. For a typical two dimensional (2D) BEC we focus on two limiting cases, the weak- and strong-coupling regimes, where a perturbation theory and the Thomas-Fermi approximation, respectively, are valid. We calculate integrated scattering intensity spectra for probing the collective excitations of the condensate in both considered limits. Moreover, in relation to recent experiments on optical modulation allowing localization of condensates in a trap with well controlled shape and dimensions, we study the quasi-one dimensional (1D) motion of the BEC in microwires and report the corresponding Bogolyubov's excitation spectrum. We show that in 1D case the characteristic polariton-polariton interaction constant is expressed as $g_{1}=3\lambda \mathcal{N}/(2L_{y})$ ($\lambda $ is the 2D polariton-polaritons interaction parameter in the cavity, $\mathcal{N}$ the number of the particles, and $L_{y}$ the wirecavity width). We reveal some interesting features for 2D and 1D Bogolyubov spectra for both repulsive $(\lambda >0)$ and attractive $(\lambda <0)$ interaction., Comment: 12 pages, 6 figures

Published
2014
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16. Spin filtering in nanowire directional coupler

Author

Dias, M. Rebello Sousa, Lopez-Richard, V., Marques, G. E., and Ulloa, S. E.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

The spin transport characteristics of a nanowire directional electronic coupler have been evaluated theoretically via a transfer matrix approach. The application of a gate field in the region of mixing allows for control of spin current through the different leads of the coupler via the Rashba spin-orbit interaction. The combination of spin-orbit interaction and applied gate voltages on different legs of the coupler give rise to a controllable modulation of the spin polarization. Both structural factors and field strength tuning lead to a rich phenomenology that could be exploited in spintronic devices., Comment: 9 pages, 4 figures

Published
2013
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17. Aharonov-Bohm Effect for Neutral Excitons in Quantum Rings

Author

Teodoro, M. D., Campo Jr., V. L., López-Richard, V., Marega Jr., E., Marques, G. E., Salamo, G. J., Avouris, Phaedon, Series Editor, Bhushan, Bharat, Series Editor, Bimberg, Dieter, Series Editor, von Klitzing, Klaus, Series Editor, Ning, Cun-Zheng, Series Editor, Wiesendanger, Roland, Series Editor, and Fomin, Vladimir M., editor

Published
2018
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18. Tuning hole mobility in InP nanowires

Author

Dias, M. Rebello Sousa, Picinin, A., Lopez-Richard, V., Ulloa, S. E., Castelano, L. K., Rino, J. P., and Marques, G. E.

Subjects
Condensed Matter - Materials Science
Abstract

Transport properties of holes in InP nanowires were calculated considering electron-phonon interaction via deformation potentials, the effect of temperature and strain fields. Using molecular dynamics, we simulate nanowire structures, LO-phonon energy renormalization and lifetime. The valence band ground state changes between light- and heavy-hole character, as the strain fields and the nanowire size are changed. Drastic changes in the mobility arise with the onset of resonance between the LO-phonons and the separation between valence subbands., Comment: 4 pages, 4 figures

Published
2012
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19. Superfluidity and collective oscillations of trapped Bose-Einstein condensates in a periodical potential

Author

Trallero-Giner, C., Lopez-Richard, V., Núñez-Fernández, Y., Oliva, Maurice, and Chung, Ming-Chiang

Subjects
Condensed Matter - Quantum Gases
Abstract

Based on a unified theoretical treatment of the 1D Bogoliubov-de Genes equations, the superfluidity phenomenon of the Bose-Einstein condensates (BEC) loaded into trapped optical lattice is studied. Within the perturbation regime, an all-analytical framework is presented enabling a straightforward phenomenological mapping of the collective excitation and oscillation character of a trapped BEC where the available experimental configurations also fit., Comment: 5 pages and 2 Figs, some errors have been corrected in versions 2

Published
2011
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20. Aharonov-Bohm interference in quantum ring exciton: effects of built-in electric fields

Author

Teodoro, M. D., Campo Jr., V. L., Lopez-Richard, V., Marega Jr., E., Marques, G. E., Galvao-Gobato, Y., Iikawa, F., Brasil, M. J. S. P., AbuWaar, Z. Y., Dorogan, V. G., Mazur, Yu. I., Benamara, M., and Salamo, G. J.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We report a comprehensive discussion of quantum interference effects due to the finite structure of excitons in quantum rings and their first experimental corroboration observed in the optical recombinations. Anomalous features that appear in the experiments are analyzed according to theoretical models that describe the modulation of the interference pattern by temperature and built-in electric fields., Comment: 6 pages, 7 figures

Published
2009
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21. Bose-Einstein condensation in an optical lattice: A perturbation approach

Author

Trallero-Giner, C., Lopez-Richard, V., Chung, Ming-Chiang, and Buchleitner, Andreas

Subjects
Condensed Matter - Other Condensed Matter
Abstract

We derive closed analytical expressions for the order parameter $\Phi (x)$ and for the chemical potential $\mu $ of a Bose-Einstein Condensate loaded into a harmonically confined, one dimensional optical lattice, for sufficiently weak, repulsive or attractive interaction, and not too strong laser intensities. Our results are compared with exact numerical calculations in order to map out the range of validity of the perturbative analytical approach. We identify parameter values where the optical lattice compensates the interaction-induced nonlinearity, such that the condensate ground state coincides with a simple, single particle harmonic oscillator wave function.

Published
2008
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22. Formal analytical solutions for the Gross-Pitaevskii equation

Author

Trallero-Giner, C., Drake-Perez, Julio C., Lopez-Richard, V., and Birman, Joseph L.

Subjects
Condensed Matter - Other Condensed Matter
Abstract

Considering the Gross-Pitaevskii integral equation we are able to formally obtain an analytical solution for the order parameter $\Phi (x)$ and for the chemical potential $\mu $ as a function of a unique dimensionless non-linear parameter $\Lambda $. We report solutions for different range of values for the repulsive and the attractive non-linear interactions in the condensate. Also, we study a bright soliton-like variational solution for the order parameter for positive and negative values of $\Lambda $. Introducing an accumulated error function we have performed a quantitative analysis with other well-established methods as: the perturbation theory, the Thomas-Fermi approximation, and the numerical solution. This study gives a very useful result establishing the universal range of the $\Lambda $-values where each solution can be easily implemented. In particular we showed that for $\Lambda <-9$, the bright soliton function reproduces the exact solution of GPE wave function., Comment: 8 figures

Published
2007
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23. Electric field inversion asymmetry: Rashba and Stark effects for holes in resonant tunneling devices

Author

de Carvalho, H. B., Brasil, M. J. S. P., Lopez-Richard, V., Camps, I., Gobato, Y. Galvao, Marques, G. E., Dacal, L. C. O., Henini, M., Eaves, L., and Hill, G.

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science
Abstract

We report experimental evidence of excitonic spin-splitting, in addition to the conventional Zeeman effect, produced by a combination of the Rashba spin-orbit interaction, Stark shift and charge screening. The electric-field-induced modulation of the spin-splitting are studied during the charging and discharging processes of p-type GaAs/AlAs double barrier resonant tunneling diodes (RTD) under applied bias and magnetic field. The abrupt changes in the photoluminescence, with the applied bias, provide information of the charge accumulation effects on the device., Comment: 4 pages, 2 figures

Published
2006
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24. Inadequacy of equivalent circuits in nonlinear systems with inherent memory

Author

Lopez-Richard, V., Silva, R. S. Wengenroth, Lipan, O., and Hartmann, F.

Subjects
FOS: Physical sciences, Applied Physics (physics.app-ph), Physics - Applied Physics
Abstract

Basic multimode impedance analysis grounded in the availability of nonequilibrium charge carriers and their retarded path towards equilibrium is used to access the inadequacy of equivalent circuits in nonlinear systems with inherent memory. On the basic grounds of coexisting generation and trapping sites and their relaxation times, we show how seeming complexity of frequency-dependent impedance that matches a vast universe of experimental evidences can be reduced to simple combinations of basic microscopic ingredients. The emergence of counterintuitive features such as a negative capacitances or unexpected inductances becomes a metaphoric construction with poor physical meaning, pointing to the limitations and ambiguities of the symbolic nature of "equivalent" circuits. Our approach further provides a microscopic perspective that exposes the linkage of an apparent flux with an apparent inductance dismissing any magnetic essence., 9 pages, 10 figures

Published
2023

25. Aharonov-Bohm Effect for Neutral Excitons in Quantum Rings

Author

Teodoro, M. D., Campo, V. L., Jr., Lopez-Richard, V., Marega, E., Jr., Marques, G. E., Salamo, G. J., Avouris, Phaedon, Series editor, Bhushan, Bharat, Series editor, Bimberg, Dieter, Series editor, von von Klitzing, Klaus, Series editor, Sakaki, Hiroyuki, Series editor, Wiesendanger, Roland, Series editor, and Fomin, Vladimir M., editor

Published
2014
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26. Evidence for the formation of metallic In after laser irradiation of InP.

Author

Cabral, L., Andrés, J., Machado, T. R., Picinin, A., Rino, J. P., Lopez-Richard, V., Longo, E., Gouveia, A. F., Marques, G. E., da Silva, E. Z., and San-Miguel, M. A.

Subjects
THERMAL neutrons, LASERS, COULOMB explosion, DENSITY functional theory, IRRADIATION, TRANSMISSION electron microscopy
Abstract

Structural and electronic changes induced by laser irradiation are currently of interest owing to the possibility to tune the mechanical, optical, and transport properties of the irradiated materials. In this work, we investigate the effects of laser irradiation on indium phosphide, InP, by modifying the electronic temperature, T e , of the system within the density functional theory framework and performing molecular dynamics simulations to prove that the laser irradiation also provokes a local thermalization effect. We found that the process can be described by a two-stage mechanism. First, at low T e values (0–1.0 eV), the laser energy induces electronic transitions, while the InP lattice remains undisturbed and cool. In the second stage (with T e in the range of 1.0–4.0 eV), both electron-electron scattering and electron-phonon coupling processes are triggered, increasing the energy of the lattice so as to provoke a Coulomb explosion, which changes some physical chemical properties of InP. The close agreement between the simulations helps explain the formation of metallic In as it is observed in the transmission electron microscopy images. [ABSTRACT FROM AUTHOR]

Published
2019
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28. Optical Mapping of Nonequilibrium Charge Carriers

Author

Guarin Castro, E. D., primary, Pfenning, A., additional, Hartmann, F., additional, Knebl, G., additional, Daldin Teodoro, M., additional, Marques, G. E., additional, Höfling, S., additional, Bastard, G., additional, and Lopez-Richard, V., additional

Published
2021
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34. Temperature tuning from direct to inverted bistable electroluminescence in resonant tunneling diodes.

Author

Hartmann, F., Pfenning, A., Sousa Dias, M. Rebello, Langer, F., Höfling, S., Kamp, M., Worschech, L., Castelano, L. K., Marques, G. E., and Lopez-Richard, V.

Subjects
ELECTROLUMINESCENCE, ELECTRIC field effects, RESONANT tunneling, QUANTUM interference, OPTOELECTRONICS
Abstract

We study the electroluminescence (EL) emission of purely n-doped resonant tunneling diodes in a wide temperature range. The paper demonstrates that the EL originates from impact ionization and radiative recombination in the extended collector region of the tunneling device. Bistable current-voltage response and EL are detected and their respective high and low states are tuned under varying temperature. The bistability of the EL intensity can be switched from direct to inverted with respect to the tunneling current and the optical on/off ratio can be enhanced with increasing temperature. One order of magnitude amplification of the optical on/off ratio can be attained compared to the electrical one. Our observation can be explained by an interplay of moderate peak-to-valley current ratios, large resonance voltages, and electron energy loss mechanisms, and thus, could be applied as an alternative route towards optoelectronic applications of tunneling devices. [ABSTRACT FROM AUTHOR]

Published
2017
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35. Dielectric response in narrow-gap semiconductor quantum wells in a magnetic field

Author

Lopez-Richard, V., Marques, G.E., and Trallero-Giner, C.

Subjects
Physics -- Research, Quantum wells -- Research, Semiconductors -- Research, Physics
Abstract

Research describing the dielectric response of narrow gap semiconductor structures is presented. In particular intraband transitions in a quasi-two dimensional electron plasma are investigated.

Published
2001

37. Mimicking of pulse shape-dependent learning rules with a quantum dot memristor.

Author

Maier, P., Hartmann, F., Sousa Dias, M. Rebello, Emmerling, M., Schneider, C., Castelano, L. K., Kamp, M., Marques, G. E., Lopez-Richard, V., Worschech, L., and Höoflin, S.

Subjects
QUANTUM dots, MEMRISTORS, ELECTRONS, QUANTUM tunneling, ELECTRIC conductivity
Abstract

We present the realization of four different learning rules with a quantum dot memristor by tuning the shape, the magnitude, the polarity and the timing of voltage pulses. The memristor displays a large maximum to minimum conductance ratio of about 57 000 at zero bias voltage. The high and low conductances correspond to different amounts of electrons localized in quantum dots, which can be successively raised or lowered by the timing and shapes of incoming voltage pulses. Modifications of the pulse shapes allow altering the conductance change in dependence on the time difference. Hence, we are able to mimic different learning processes in neural networks with a single device. In addition, the device performance under pulsed excitation is emulated combining the Landauer-Büttiker formalism with a dynamic model for the quantum dot charging, which allows explaining the whole spectrum of learning responses in terms of structural parameters that can be adjusted during fabrication, such as gating efficiencies and tunneling rates. The presented memristor may pave the way for future artificial synapses with a stimulus-dependent capability of learning. [ABSTRACT FROM AUTHOR]

Published
2016
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38. Carrier transfer in vertically stacked quantum ring-quantum dot chains.

Author

Mazur, Yu. I., Lopes-Oliveira, V., de Souza, L. D., Lopez-Richard, V., Teodoro, M. D., Dorogan, V. G., Benamara, M., Wu, J., Tarasov, G. G., Marega Jr., E., Wang, Z. M., Marques, G. E., and Salamo, G. J.

Subjects
QUANTUM rings, QUANTUM dots, MOLECULAR beam epitaxy, INDIUM gallium arsenide, GALLIUM arsenide, TEMPERATURE
Abstract

The interplay between structural properties and charge transfer in self-assembled quantum ring (QR) chains grown by molecular beam epitaxy on top of an InGaAs/GaAs quantum dot (QD) superlattice template is analyzed and characterized. The QDs and QRs are vertically stacked and laterally coupled as well as aligned within each layer due to the strain field distributions that governs the ordering. The strong interdot coupling influences the carrier transfer both along as well as between chains in the ring layer and dot template structures. A qualitative contrast between different dynamic models has been developed. By combining temperature and excitation intensity effects, the tuning of the photoluminescence gain for either the QR or the QD mode is attained. The information obtained here about relaxation parameters, energy scheme, interlayer and interdot coupling resulting in creation of 1D structures is very important for the usage of such specific QR-QD systems for applied purposes such as lasing, detection, and energy-harvesting technology of future solar panels. [ABSTRACT FROM AUTHOR]

Published
2015
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39. Electroluminescence on-off ratio control off n−i−n GaAs/AlGaAs-based resonant tunneling structures

Author

Cardozo de Oliveira, E. R., Pfenning, A., Guarin Castro, E. D., Teodoro, M. D., dos Santos, E. C., Lopez-Richard, V., Marques, G. E., Worschech, L., Hartmann, F., Höfling, S., University of St Andrews. School of Physics and Astronomy, and University of St Andrews. Condensed Matter Physics

Subjects
QC Physics, TK, Physics::Space Physics, NDAS, QC, TK Electrical engineering. Electronics Nuclear engineering
Abstract

We explore the nature of the electroluminescence (EL) emission of purely n-doped GaAs/AlGaAs resonant tunneling diodes (RTDs) and the EL evolution with voltage. A singular feature of such a device is unveiled when the electrical output current changes from higher to lower values and the EL on-off ratio is enhanced by two orders of magnitude compared to the current on-off ratio. By combining the EL and the current properties, we are able to identify two independent impact ionization channels associated with the coherent resonant tunneling current and the incoherent valley current. We also perform the same investigation with an associated series resistance, which induces a bistable electrical output in the system. By simulating a resistance variation for the current voltage and the EL, we are able to tune the EL on-off ratio by up to six orders of magnitude. We further observe that the EL on and off states can be either direct or inverted compared to the tunneling current of the on and off states. This electroluminescence, combined with the unique RTD properties, such as the negative differential resistance and high-frequency operation, enables the development of high-speed functional optoelectronic devices and optical switches. Publisher PDF

Published
2018

40. Electron transport in quantum dot chains: Dimensionality effects and hopping conductance.

Author

Kunets, Vas. P., Rebello Sousa Dias, M., Rembert, T., Ware, M. E., Mazur, Yu. I., Lopez-Richard, V., Mantooth, H. A., Marques, G. E., and Salamo, G. J.

Subjects
ELECTRON transport, QUANTUM dots, HOPPING conduction, ANISOTROPY, SEMICONDUCTOR research
Abstract

Detailed experimental and theoretical studies of lateral electron transport in a system of quantum dot chains demonstrate the complicated character of the conductance within the chain structure due to the interaction of conduction channels with different dimensionalities. The one-dimensional character of states in the wetting layer results in an anisotropic mobility, while the presence of the zero-dimensional states of the quantum dots leads to enhanced hopping conductance, which affects the low-temperature mobility and demonstrates an anisotropy in the conductance. These phenomena were probed by considering a one-dimensional model of hopping along with band filling effects. Differences between the model and the experimental results indicate that this system does not obey the simple one-dimensional Mott's law of hopping and deserves further experimental and theoretical considerations. [ABSTRACT FROM AUTHOR]

Published
2013
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44. Gate-controlled electron g-factor in lateral quantum dot molecules.

Author

Ribeiro-Santos, D., Qu, Fanyao, Morais, P. C., Lopez-Richard, V., and Marques, G. E.

Subjects
QUANTUM dots, ELECTRONS, ELECTRIC fields, MAGNETIC fields, GAUSSIAN processes, HILBERT space, QUANTUM wells, HETEROSTRUCTURES
Abstract

We investigate theoretically the tunability of the effective electron g-factor in lateral double quantum dots, subjected simultaneously to spin-orbit interaction and vertical electrical and magnetic fields. We find that, by sweeping interdot barrier voltage or by changing interdot distance, the character of the electronic states can be modified from atomic-like to molecular-like and vice-versa. We report theoretical predictions for interdot voltage induced giant effective g-factor and study its dependence on the spin-orbit interaction strength. To avoid numerical artifacts in the single-electron energy spectrum, we adopt a set of modified Gaussian functions as basis, divide the full Hilbert space into orthogonal sub-spaces, and use an exact diagonalization method. In order to correct ill-definitions of g-factor found in the literature, we point out an unambiguous way to evaluate it. [ABSTRACT FROM AUTHOR]

Published
2011
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46. Tunability of magnetization in lateral few electron double quantum dots

Author

Fanyao Qu, Santos, D.R. Jr., Morais, P.C., Lopez-Richard, V., and Marques, G.E.

Subjects
Magnetization -- Analysis, Indium -- Magnetic properties, Indium -- Chemical properties, Magnetic susceptibility -- Analysis, Physics
Abstract

The article presents different ways that can be adopted for tuning the magnetic properties exhibited by the tunable lateral double InAs quantum dots consisting of two-electrons. The magnitude of magnetization and susceptibility of the quantum dots is shown to highly depend on the spin-orbit interaction taking place in the system.

Published
2010

48. Nanoscale Tipping Bucket Effect in a Quantum Dot Transistor-Based Counter

Author

Hartmann, F., primary, Maier, P., additional, Rebello Sousa Dias, M., additional, Göpfert, S., additional, Castelano, L. K., additional, Emmerling, M., additional, Schneider, C., additional, Höfling, S., additional, Kamp, M., additional, Pershin, Y. V., additional, Marques, G. E., additional, Lopez-Richard, V., additional, and Worschech, L., additional

Published
2017
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