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Study of AlGaN/GaN quantum structure fabricated by Focus ion beamChang, Yung-Shi 28 July 2009 (has links)
We have observed a large spin-splitting in device made of AlxGa1-xN/GaN quantum wires. Based on this observation, we proposed a new spintronic application, the spin-hall quantum-ring interferometer, by the spin-Hall effect, Rashba and Dresselhaus effects. This device we use the ICP Etch System to etch the contact pattern, and then use the Multi-Target Sputter to deposit the protecting layer, and then use the E-Beam Evaporator to make the contact. Finally, using the Focus Ion Beam, we fabricate the quantum-ring and gate successfully. This thesis is focused on discussing the design of the fabrication and try to solve the problem in order to be able to detect the signal of the quantum-ring interferometer at low temperature and high magnetic condition.
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Many-Body effects in Semiconductor NanostructuresWesslén, Carl-Johan January 2014 (has links)
Low dimensional semiconductor structures are modeled using techniques from the field of many-body atomic physics. B-splines are used to create a one-particle basis, used to solve the more complex many-body problems. Details on methods such as the Configuration Interaction (CI), Many-Body Perturbation Theory (MBPT) and Coupled Cluster (CC) are discussed. Results from the CC singles and doubles method are compared to other high-precision methods for the circular harmonic oscillator quantum dot. The results show a good agreement for the energy of many-body states of up to 12 electrons. Properties of elliptical quantum dots, circular quantum dots, quantum rings and concentric quantum rings are all reviewed. The effects of tilted external magnetic fields applied to the elliptical dot are discussed, and the energy splitting between the lowest singlet and triplet states is explored for varying geometrical properties. Results are compared to experimental energy splittings for the same system containing 2 electrons.
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Efeitos da interação elétron-elétron na estrutura eletrônica e nas propriedades de transporte em pontos quânticos e anéis quânticos semicondutores / Effects of electron-electron interaction on the electronic structure and on the transport properties of semiconductor quantum dots and quantum ringsCastelano, Leonardo Kleber 19 December 2006 (has links)
Esta tese é composta por duas partes. Na primeira parte, os efeitos da interação elétron-elétron nas configurações do estado fundamental de dois anéis quânticos acoplados (CQRs) são estudados. Os CQRs podem formar um novo tipo de molécula artificial, onde o raio dos anéis juntamente com a distância entre os anéis, são novos parâmetros ajustáveis que fornecem novos graus de liberdade para controlar a estrutura eletrônica destas moléculas. Através da bem estabelecida teoria do funcional densidade dependente de spin, as configurações ou fases do estado fundamental dos CQRs com alguns elétrons são determinadas. Uma rica variedade de fases para o estado fundamental destas novas moléculas artificiais é encontrada para sistemas contendo até N=13 elétrons. Para CQRs com N menor ou igual a 8 são obtidas qualitativamente configurações para o estado fundamental similares às dos pontos quânticos acoplados (CQDs). As novas configurações eletrônicas aparecem para N maior ou igual a 9. Na segunda parte desta tese é desenvolvido um método numérico para estudar o espalhamento eletrônico através de um ponto quântico com N-elétrons confinados. Considera-se que o ponto quântico está imerso num sistema bidimensional ou confinado em um canal unidimensional. As taxas de espalhamento são obtidas resolvendo iterativamente a equação de Lippmann-Schwinger incluindo a interação elétron-elétron entre o elétron incidente e os N-elétrons confinados dentro do QD. Para exemplificar, este método é aplicado para um elétron externamente injetado sobre um QD contendo um único elétron. As taxas de espalhamento elástico, inelástico e de spin-flip são obtidas. Os efeitos da interação de troca no espalhamento eletrônico e transporte através do QD são analisados.Também são considerados os processos do espalhamento multi-canal neste sistema e suas influências nas propriedades de transporte. / This thesis is composed of two parts. In the first part, we study the effects of electron-electron interactions on the ground state configurations of two vertically coupled quantum rings (CQRs). The CQRs can form a new type of artificial molecule (AM) where the ring radius together with the inter-ring distance are new tunable parameters providing new degrees of freedom to modulate and control the electronic structure of the artificial ring shaped molecules. In this work, we apply the well established spin-density functional theory to study the ground state configurations or phases of few-electron CQRs. A rich range of ground state phases of these new quantum ring AMs is uncovered for systems containing up to N = 13 electrons. For CQRs with N less or equal to 8 we found qualitatively similar ground state phases as for coupled quantum dots (CQDs). Novel phases appear for N greater or equal to 9. In the second part of this thesis, we develop a numerical method to study the electron scattering through an occupied quantum dot (QD) with a few electrons. The QD is considered embedded in a two-dimensional system or confined in a one-dimemsional channel. An external electron is injected and scattered through the QD. The scattering rates are obtained by solving iteratively the Lippmann-Schwinger equation including the electron-electron interactions between the incident electron and the N-electrons confined in the QD. As an example, we apply this model for an externally injected electron through a QD with one electron inside. The elastic, inelastic, and spin-flip scattering rates are obtained. The effects of electron exchange interaction on the electron scattering and transport through the QD are analyzed. We also show the multi-channel scattering processes in such systems and their influences on the electron transport properties.
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Anéis quânticos em grafeno na presença de defeitos topológicosSilva Neto, José Amaro da 25 March 2013 (has links)
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Previous issue date: 2013-03-25 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / The Graphene is a two-dimensional(2-D) semiconductor crystal with null gap, where
charge carriers behave as massless particles. In this speci c dynamics in the limit of
low energies, the energy dispersion relation is linear, and this material can be described
by massless Dirac equation contrasts with the semiconductors, for which the charge carriers
are massive. In this framework, there is the problem of the electronic con nement
in graphene because of tunneling. For overcome this di culty, is proposed a new model
of quantum ring, based on Dirac oscillator and models of rings Tan-Inkson and Bakke-
Furtado. From this new coupling, are obtainable the energy spectrum, persistent currents
and positive spinors to a graphene sheet with / without topological defect type disclination
by massless Dirac equation (2+1). / O grafeno e um cristal bidimensional(2-D) semicondutor com gap nulo, onde os portadores
de cargas se comportam como part culas sem massa. Nesta din^amica espec ca, no limite
de baixas energias, a rela c~ao de dispers~ao de energia e linear, sendo que este material
pode ser descrito pela equa c~ao de Dirac sem massa contrastando com os semicondutores,
cujos portadores de cargas t^em massa. Neste quadro, h a o problema do con namento
eletr^onico no grafeno devido ao tunelamento. Para contornar esta di culdade, e proposto
um novo modelo de anel qu^antico, baseado no oscilador de Dirac e nos modelos de an eis
de Tan-Inkson e Bakke-Furtado. A partir desse novo acoplamento, s~ao obtidos o espectro
de energia, as correntes persistentes e os espinores positivos para uma folha de grafeno
com/sem defeito topol ogico do tipo desclina c~ao, via equa c~ao de Dirac (2+1) sem massa
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Efeitos da interação elétron-elétron na estrutura eletrônica e nas propriedades de transporte em pontos quânticos e anéis quânticos semicondutores / Effects of electron-electron interaction on the electronic structure and on the transport properties of semiconductor quantum dots and quantum ringsLeonardo Kleber Castelano 19 December 2006 (has links)
Esta tese é composta por duas partes. Na primeira parte, os efeitos da interação elétron-elétron nas configurações do estado fundamental de dois anéis quânticos acoplados (CQRs) são estudados. Os CQRs podem formar um novo tipo de molécula artificial, onde o raio dos anéis juntamente com a distância entre os anéis, são novos parâmetros ajustáveis que fornecem novos graus de liberdade para controlar a estrutura eletrônica destas moléculas. Através da bem estabelecida teoria do funcional densidade dependente de spin, as configurações ou fases do estado fundamental dos CQRs com alguns elétrons são determinadas. Uma rica variedade de fases para o estado fundamental destas novas moléculas artificiais é encontrada para sistemas contendo até N=13 elétrons. Para CQRs com N menor ou igual a 8 são obtidas qualitativamente configurações para o estado fundamental similares às dos pontos quânticos acoplados (CQDs). As novas configurações eletrônicas aparecem para N maior ou igual a 9. Na segunda parte desta tese é desenvolvido um método numérico para estudar o espalhamento eletrônico através de um ponto quântico com N-elétrons confinados. Considera-se que o ponto quântico está imerso num sistema bidimensional ou confinado em um canal unidimensional. As taxas de espalhamento são obtidas resolvendo iterativamente a equação de Lippmann-Schwinger incluindo a interação elétron-elétron entre o elétron incidente e os N-elétrons confinados dentro do QD. Para exemplificar, este método é aplicado para um elétron externamente injetado sobre um QD contendo um único elétron. As taxas de espalhamento elástico, inelástico e de spin-flip são obtidas. Os efeitos da interação de troca no espalhamento eletrônico e transporte através do QD são analisados.Também são considerados os processos do espalhamento multi-canal neste sistema e suas influências nas propriedades de transporte. / This thesis is composed of two parts. In the first part, we study the effects of electron-electron interactions on the ground state configurations of two vertically coupled quantum rings (CQRs). The CQRs can form a new type of artificial molecule (AM) where the ring radius together with the inter-ring distance are new tunable parameters providing new degrees of freedom to modulate and control the electronic structure of the artificial ring shaped molecules. In this work, we apply the well established spin-density functional theory to study the ground state configurations or phases of few-electron CQRs. A rich range of ground state phases of these new quantum ring AMs is uncovered for systems containing up to N = 13 electrons. For CQRs with N less or equal to 8 we found qualitatively similar ground state phases as for coupled quantum dots (CQDs). Novel phases appear for N greater or equal to 9. In the second part of this thesis, we develop a numerical method to study the electron scattering through an occupied quantum dot (QD) with a few electrons. The QD is considered embedded in a two-dimensional system or confined in a one-dimemsional channel. An external electron is injected and scattered through the QD. The scattering rates are obtained by solving iteratively the Lippmann-Schwinger equation including the electron-electron interactions between the incident electron and the N-electrons confined in the QD. As an example, we apply this model for an externally injected electron through a QD with one electron inside. The elastic, inelastic, and spin-flip scattering rates are obtained. The effects of electron exchange interaction on the electron scattering and transport through the QD are analyzed. We also show the multi-channel scattering processes in such systems and their influences on the electron transport properties.
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On the role of the electron-electron interaction in two-dimensional quantum dots and ringsWaltersson, Erik January 2010 (has links)
Many-Body Perturbation Theory is put to test as a method for reliable calculations of the electron-electron interaction in two-dimensional quantum dots. We show that second order correlation gives qualitative agreement with experiments on a level which was not found within the Hartree-Fock description. For weaker confinements, the second order correction is shown to be insufficient and higher order contributions must be taken into account. We demonstrate that all order Many-Body Perturbation Theory in the form of the Coupled Cluster Singles and Doubles method yields very reliable results for confinements close to those estimated from experimental data. The possibility to use very large basis sets is shown to be a major advantage compared to Full Configuration Interaction approaches, especially for more than five confined electrons. Also, the possibility to utilize two-electron correlation in combination with tailor made potentials to achieve useful properties is explored. In the case of a two-dimensional quantum dot molecule we vary the interdot distance, and in the case of a two-dimensional quantum ring we vary the ring radius, in order to alter the spectra. In the latter case we demonstrate that correlation in combination with electromagnetic pulses can be used for the realization of quantum logical gates. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 5: Manuscript.
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