Fotodetectores de radiação infravermelha baseados em pontos quânticos de submonocamada / Infrared photodetectors based on submonolayer quantum dots.

Zeidan, Ahmad Al

03 October 2017

Nesse trabalho, foi investigado um novo tipo de fotodetector de radiação infravermelha baseado em pontos quânticos de submonocamada de InAs obtidos pela técnica de epitaxia por feixe molecular (MBE, Molecular Beam Epitaxy). Suas propriedades foram comparadas com as de fotodetectores de pontos quânticos de InAs convencionais obtidos pela mesma técnica de deposição, mas no modo de crescimento Stranski-Krastanov. Medidas de corrente de escuro, de ruído, de responsividade e de absorção mostraram que, dependendo da estrutura das amostras, os dispositivos com pontos quânticos de submonocamada podem ter um excelente desempenho. / In this work, we investigated a new type of infrared photodetector based on InAs sub-monolayer quantum dots grown by molecular beam epitaxy (MBE). Their properties were compared with those of photodetectors containing conventional InAs quantum dots obtained by the same deposition technique, but in the Stranski-Krastanov growth mode. Dark current, noise, responsivity and absorption measurements have shown that, depending on the structure of the samples, the devices with sub-monolayer quantum dots can perform very well.

Epitaxia por feixes moleculares.

Fotodetectores

InAs

InAs

Infrared

infravermelho

Molecular beam epitaxy

Photodetectors

Pontos quânticos

Quantum dots

Submonocamada

Submonolayer

Síntese de nanofios de óxidos semicondutores para aplicações em dispositivos ópticos e eletrônicos

Savu, Raluca [UNESP]

16 November 2009

Made available in DSpace on 2014-06-11T19:31:04Z (GMT). No. of bitstreams: 0 Previous issue date: 2009-11-16Bitstream added on 2014-06-13T19:01:19Z : No. of bitstreams: 1 savu_r_dr_bauru.pdf: 10688901 bytes, checksum: 4c1846c73d88b2e598b43e7a14ea1b7c (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / A presente pesquisa teve como principal objetivo a obtenção de estruturas nanométricas de óxido de índio, óxido de estanho e óxido de zinco por evaporação térmica e síntese hidrotérmica e a construção e teste de sensores de gases e de fotodetectores de ultravioleta baseados nessas nanoestruturas. Foram realizados estudos da influência dos parâmetros experimentais das duas rotas de síntese usadas sobre as morfologias e as propriedades das estruturas. Para a obtenção das camadas nanoestruturadas por evaporação térmica foi especialmente construído um forno tubular que permitiu o controle da temperatura de deposição independente da temperatura de evaporação e da distância entre a fonte de evaporação e o substrato. Esses parâmetros, pouco explorados nas pesquisas reportadas na literatura, exerceram uma grande influência sobre a morfologia e as propriedades dos nanofios obtidos. O equipamento permitiu ainda um controle preciso da composição da atmosfera e da pressão de síntese. Na síntese química em solução, a construção de um reator hidrotérmico permitiu o estudo da influência da taxa de resfriamento sobre as dimensões, cristalinidade, morfologia e propriedades das nanoestruturas. Esse estudo, o primeiro do gênero na literatura, ressaltou a importância no controle deste parâmetro para sintetizar estruturas com propriedades melhoradas. As demais variáveis estudadas foram: a concentração das soluções, as camadas catalisadoras, a temperatura e o tempo de síntese. Foram testadas duas estratégias para a obtenção dos filmes nanoestruturados: spin-coating de suspensões de nanoestruturas sobre substratos de silício oxidado ou o crescimento das mesmas, durante a síntese, sobre substratos com camadas catalisadoras de zinco. Os nanofios e as camadas funcionais foram caracterizados por Difração de Raios-X (DRX), Microscopia Eletrônica de Varredura... / The subject of this thesis covers the synthesis and growth of indium, tin and zinc oxide nanostructures by thermal evaporation and hydrothermal synthesis and the fabrication and testing of gas sensors and ultraviolet photodetectors based on these nanosized structures. For both chemical and physical routes, the influence of processing conditions over the morphology, dimensions and electrical properties of the nanowires was investigated. In order to obtain nanostructured layers by thermal evaporation a tubular furnace was specifically builti, allowed the control of the source-substrate distance and the deposition temperature independently of the evaporation one. These parameters, slightly explored in the literature, granted a big influence over the nanowires morphology and properties. Moreover, the equipment permitted the control of deposition atmosphere and pressure. The design and assembly of a hydrothermal reactor allowed studying the influence of the cooling rate over the dimension, morphology, cristallinity and, consequently, the properties of the nanostructures. This study highlighted the importance of controlling this particular parameter in the hydrothermal process, yielding nanostructured materials with enhanced properties. Variables such as solution concentration, synthesis temperature and time, surfanctants and precursors were also explored in the hydrothermal process. In order to obtain nanostructured thin films using the chemical bath deposition, two processing techniques were employed: spin-coating of powder suspensions over oxidized silicon substrates and nanostructured anisotropic growth directly from solution using zinc coated substrates. The nanowires and the functional nanostructured layers were characterized by X-Ray Diffraction (XRD), Field Emission Scanning Electron Microscopy (FE - SEM), Transmission Electron Microscopy (TEM) and X-ray Photoelectron Spectroscopy (XPS)... (Complete abstract click electronic access below)

Nanoestrutura

Detectores

Óxidos semicondutores

Evaporação térmica

Síntese hidrotérmica

Nanostructures

Semiconducting oxides

Thermal evaporation

Hydrothermal synthesis

Gas sensors

Ultraviolet photodetectors

Crescimento, fabricação e teste de fotodetectores de radiação infravermelha baseados em pontos quânticos / Growth fabrication and testing of quantum-dots infrared photodetectors

Maia, Álvaro Diego Bernardino

31 August 2012

Os fotodetectores infravermelhos baseados em pontos quânticos (Quantum-dot Infrared Photodetectors, QDIPs) surgiram recentemente como uma nova tecnologia para a detecção de radiação infravermelha. Comparados com fotodetectores mais convencionais baseados em poços quânticos (Quantum-well Infrared Photodetectors, QWIPs), as suas vantagens se originam no confinamento tridimensional de portadores e incluem a sensibilidade intrínseca à incidência normal de luz, um maior tempo de vida dos portadores fotoexcitados e uma baixa corrente de escuro, que devem permitir o funcionamento dos dispositivos acima das temperaturas criogênicas. No presente trabalho, a técnica de epitaxia por feixe molecular (Molecular-Beam Epitaxy - MBE) foi usada para crescer várias amostras de QDIPs de InAs/GaAs com o objetivo de estudar a inuência dos parâmetros estruturais destes dispositivos. Após o crescimento, as amostras foram processadas em pequenas mesas quadradas por técnicas de litografia convencional e, então, caracterizadas. As propriedades ópticas e eletrônicas dos dispositivos foram verificadas para temperaturas a partir de 10 K. Com o objetivo de realizar medidas eletrônicas de alta qualidade, janelas de Ge e cabos com conectores de baixo ruído para baixa temperatura foram empregados. As curvas de corrente de escuro, as curvas de responsividade com corpo negro (fotocorrente), as medições do ruído com uma analisador de sinais e as respostas espectrais por FTIR (Fourier Transform Infrared) forneceram um conjunto completo de informações sobre os dispositivos. As figuras de mérito dos nossos melhores dispositivos permitiram também, determinar a probabilidade de captura e o ganho fotocondutivo. Com o intuito de compreender a relação entre as dimensões físicas dos pontos quânticos e as características de funcionamento dos QDIPs, desenvolveu-se um cálculo dos estados eletrônicos de da função de onda de um elétron confinado em um ponto quântico de InxGa1-xAs em formato de lente, envolvido em uma matriz de GaAs, com massas efetivas dependentes da posição. Esse modelo leva em conta o efeito da tensão assim como o gradiente de In dentro do ponto quântico, resultante do forte efeito de segregação presente em um sistema de InxGa1-xAs/GaAs. Diferentes perfis de segregação foram testados com o nosso modelo teórico com vista a proporcionar o melhor ajuste os nossos dados experimentais. / Quantum-dot Infrared Photodetectors (QDIPs) recently emerged as a new technology for detecting infrared radiation. Compared to more conventional photodetectors based on quantum wells (QWIPs), their advantages originate from the three-dimensional confinement of carriers and include an intrinsic sensitivity to normal incidence of light, a longer lifetime of the photoexcited carriers and a lower dark current which should hopefully allow their operation close to room temperature. In the present work, molecular-beam epitaxy (MBE) was used to grow several InAs/GaAs QDIP samples in order to analyse the influence the structural properties of such devices. After the growth, the samples were processed into small squared mesas by conventional lithography techniques and fully characterized. The optical and electrical properties of the devices were checked as a function of temperature using Ge optical windows and all the connectors and low-temperature/low-noise cables needed to perform high quality low-level electrical measurements. Dark-current curves, Responsivity (photocurrent) data with a black body, noise measurements with a signal analyzer and spectral responses by FTIR provided a full set of information about the devices. The figures of merit of our best devices allowed us also to determine the capture probability and the photoconductive gain. In order to understand the relationship between the physical dimensions of the quantum dots and the operating characteristics of the QDIPs, we developed a position-dependent effective-mass calculation of the bound energy levels and wave function of the electrons confined in lensshaped InxGa1-xAs quantum dots embedded in GaAs, taking into account the strain as well as the In gradient inside the quantum dots which is due to the strong In segregation and intermixing present in the InxGa1-xAs/GaAs system. Different In profiles inside the quantum dots were tested with our new theoretical model in order to provide the best _t to our experimental data.

condensed matter physics

epitaxia por feixe molecular

física da matéria condensada

fotodetectores

infrared

infravermelho

molecular bean epitaxy

photodetectors

semiconductors

semicondutores

Modeling and characterization of polycrystalline mercuric iodide radiation detectors. [electronic resource] / by Unmesh Khadilkar.

Khadilkar, Unmesh.

January 2003

Title from PDF of title page. / Document formatted into pages; contains 64 pages. / Thesis (M.E.E.)--University of South Florida, 2003. / Includes bibliographical references. / Text (Electronic thesis) in PDF format. / ABSTRACT: The ability of Mercuric Iodide (HgI2) to function as a highly efficient radiation detector at room temperature has generated great interest and has triggered further studies on this difficult material. This property is expected to enable significant enhancements to a far-ranging variety of applications and systems. HgI2 devices have shown superior performance at room temperature compared to elemental Si or Ge devices, which require to be cooled down to liquid nitrogen temperature when used as nuclear radiation detectors. While substantial studies have been conducted on single crystal HgI2, polycrystalline HgI2 remains a comparatively less studied form of this material. The primary use of HgI2 is as a direct radiation detector. It can also be used in applications with a scintillator intermediate to generate visible light from incident nuclear radiation. Hence its response to visible light can be used to study the electronic properties of HgI2 polycrystalline films. / ABSTRACT: The films are deposited on TEC-15 LOF glass with a Tin Oxide(Sn02) coating which acts as the growth surface. It also acts as the front contact with Palladium (Pd) being the back contact. Wire leads are attached to the palladium for electrical contact. The deposited films are circular in shape with a diameter of 2.5cm with thickness ranging from 50 to 600ìm. A maximum of 7 devices are contacted at various points on every film. For the measurements documented in this thesis, a tungsten-halogen lamp and an Oriel 1/4m grating monochromator are used as a light source. The incident flux on the sample is determined using a Si photodiode as reference. Device performance for both single crystal as well as polycrystalline films is documented. We have attempted to identify a set of optimum growth parameters using these measurements. / ABSTRACT: For a film to be considered favorably, not only should the individual devices show high quantum efficiencies and low dark currents, but the response of all devices on the same film should be uniform. A number of films are studied and the optimum film deposition conditions are commented upon. A powerful semiconductor device simulation tool, MEDICItm, is used to simulate the photoresponse of these films. The simulations are compared to the measurements and the transport and light absorption parameters of the polycrystalline films are determined. / System requirements: World Wide Web browser and PDF reader. / Mode of access: World Wide Web.

Radioactivity--Measurement.

Iodides.

Mercury compounds.

hgi2.

photodetectors.

optoelectronics.

medici.

compound semiconductors.

simulation.

photoresponse.

Synthesis of ZnO and transition metals doped ZnO nanostructures, their characterization and sensing applications

Chey, Chan Oeurn

January 2014

Nanotechnology is a technology of the design and the applications of nanoscale materials with their fundamentally new properties and functions. Nanosensor devices based on nanomaterials provide very fast response, low-cost, long-life time, easy to use for unskilled users, and provide high-efficiency. 1-D ZnO nanostructures materials have great potential applications in various sensing applications. ZnO is a wide band gap (3.37 eV at room temperature) semiconductor materials having large exciton binding energy (60 meV) and excellent chemical stability, electrical, optical, piezoelectric and pyroelectric properties. By doping the transition metals (TM) into ZnO matrix, the properties of ZnO nanostructures can be tuned and its room  temperature ferromagnetic behavior can be enhanced, which provide the TM-doped ZnO nanostructures as promising candidate for optoelectronic, spintronics and high performance sensors based devices. The synthesis of ZnO and TM-doped ZnO nanostructures via the low temperature hydrothermal method is considered a promising technique due to low cost, environmental friendly, simple solution process, diverse 1-D ZnO nanostructures can be achieved, and large scale production on any type of substrate, and their properties can be controlled by the growth parameters. However, to synthesize 1-D ZnO and TM-doped ZnO nanostructures with controlled shape, structure and uniform size distribution on large area substrates with desirable properties, low cost and simple processes are of high interest and it is a big challenge at present. The main purpose of this dissertation aims to develop new techniques to synthesize 1-D ZnO and (Fe, Mn)-doped ZnO nanostructures via the hydrothermal method, to characterize and to enhance their functional properties for developing sensing devices such as biosensors for clinical diagnoses and environmental monitoring applications, piezoresistive sensors and UV photodetector. The first part of the dissertation deals with the hydrothermal synthesis of ZnO nanostructures with controlled shape, structure and uniform size distribution under different conditions and their structural characterization. The possible parameters affecting the growth which can alter the morphology, uniformity and properties of the ZnO nanostructures were investigated. Well-aligned ZnO nanorods have been fabricated for high sensitive piezoresistive sensor. The development of creatinine biosensor for clinical diagnoses purpose and the development of glucose biosensor for indirect determination of mercury ions for an inexpensive and unskilled users for environmental monitoring applications with highly sensitive, selective, stable, reproducible, interference resistant, and fast response time have been fabricated based on ZnO nanorods. The second part of the dissertation presents a new hydrothermal synthesis of (Fe, Mn)-doped-ZnO nanostructures under different preparation conditions, their properties characterization and the fabrication of piezoresistive sensors and UV photodetectors based devices were demonstrated. The solution preparation condition and growth parameters that influences on the morphology, structures and properties of the nanostructures were investigated. The fabrication of Mn-doped-ZnO NRs/PEDOT:PSS Schottky diodes used as high performance piezoresistive sensor and UV photodetector have been studied and Fe-doped ZnO NRs/FTO Schottky diode has also been fabricated for high performance of UV photodetector. Finally, a brief outlook into future challenges and relating new opportunities are presented in the last part of the dissertation.

Synthesis ZnO nanostructures

TM-doped ZnO NRs

Hydrothermal method

Biosensors

Piezoresistive sensors

UV photodetectors

Diluted magnetic semiconductors

[en] DEVELOPMENT OF FAR-INFRARED PHOTODETECTORS BASED ON INTRABAND TRANSITIONS IN GAAS/ALGAAS MULTI-QUANTUM WELLS / [pt] DESENVOLVIMENTO DE FOTODETECTORES DE INFRAVERMELHO DISTANTE UTILIZANDO TRANSIÇÕES INTRABANDA EM POÇOS QUÂNTICOS MÚLTIPLOS DE GAAS/ALGAAS

MARCIO SCARPIM DE SOUZA

20 July 2006

[pt] Nas Forças Armadas do Brasil existe uma forte demanda pelo desenvolvimento de detectores de infravermelho nacionais para uso em diversas aplicações sujeitas a rígidas restrições de importação, como sistemas de imageamento infravermelho para visão noturna, guiamento de mísseis, sistemas de mira, etc. O objetivo deste trabalho foi desenvolver fotodetectores para o infravermelho distante em 10µm, baseados em estruturas semicondutoras de poços quânticos múltiplos de GaAs/AlGaAs utilizando transições intrabanda. Os materiais foram crescidos pela técnica de epitaxia de fase vapor de metalorgânicos (MOVPE). A calibração dos parâmetros de crescimento foi realizada por meio de medidas de difração de raios x, efeito Hall, e fotoluminescência. Devido à regra de seleção de que não é possível haver absorção intrabanda da luz sob incidência normal, foram aplicadas duas técnicas de acoplamento: geometria de guia de onda com incidência a 45º pela borda, e utilização de grades de difração metalizadas. Os detectores produzidos foram caracterizados quanto à corrente de escuro e quanto aos espectros de absorção óptica e de fotocorrente, ambos obtidos por espectroscopia FTIR. Ao final dos trabalhos, foi obtido um fotodetector de GaAs/AlGaAs do qual foi possível medir a fotocorrente através dos contatos elétricos do dispositivo, com pico em 9µm. Os resultados obtidos são promissores no sentido de que apontam para a possibilidade de se produzir detectores de infravermelho nacionais para diversas aplicações (defesa, medicina, astronomia, telecomunicações, etc). / [en] In the Brazilian Army there is a strong demand for the development of national infrared detectors for use in many applications subjected to severe trade restrictions, like infrared imaging systems for night vision, missile guidance, sight systems, etc. The aim of this work was to develop far- infrared photodetectors for 10µm, based on semiconductor structures of GaAs/AlGaAs multi-quantum wells using intraband transitions. The materials were grown by metalorganic vapor phase epitaxy (MOVPE). The calibration of the growing parameters was done by x ray diffraction, Hall effect, and photoluminescence measurements. Since intraband transition of light is not possible to normal incidence, due to selection rules, two coupling techniques were applied: waveguide geometry with 45o incidence on the edge, and metalized diffraction gratings. The produced detectors were characterized in terms of dark current, optical absorption and spectral response. Infrared measurements were made using FTIR spectroscopy. A GaAs/AlGaAs photodetector was obtained. The photocurrent through the electrical contacts of the device showed a peak at 9µm. The results are promising in the sense of revealing the possibility of producing national infrared photodetectors for many applications (defense, medicine, astronomy, telecommunications, etc).

[pt] SEMICONDUCTORES

[en] SEMICONDUCTORS

[pt] POCOS QUANTICOS

[en] QUANTUM WELLS

[pt] FOTODETECTORES

[en] PHOTODETECTORS

[pt] TRANSICAO INTRABANDA

[en] INTRABAND TRANSITION

[pt] INFRAVERMELHO

[en] INFRARED

[en] ELECTRONIC TRANSITION PROCESSES IN INTRABAND PHOTODETECTORS AND A CASE STUDY / [pt] OS PROCESSOS DE TRANSIÇÃO ELETRÔNICA EM FOTODETECTORES INTRABANDA E O ESTUDO DE UM CASO PARTICULAR

ERIC HERMANNY

11 July 2017

[pt] O funcionamento de detectores fotocondutivos se baseia na geração de corrente elétrica por fotoexcitação de portadores de carga. Neste trabalho, estudamos os diversos processos que contribuem para a geração de corrente em fotodetectores intrabanda (BC) e construímos um método de investigação para revelar, dentre as diferentes possibilidades, os processos que resultam na emissão eletrônica em um dispositivo concreto. Uma vez estabelecida uma metodologia, passamos ao estudo de um caso particular: um fotodetector baseado em pontos e poços quânticos acoplados, com picos de absorção no infravermelho médio. Através da comparação de espectros de absorção e fotocorrente, medidos por espectroscopia de transformada de Fourier, e de simulações computacionais para o cálculo das forças de oscilador, indicamos as transições óticas e os processos de transporte eletrônico envolvidos na fotocondutividade do dispositivo. / [en] The operation of photoconductive detectors is based on the generation of current through photoexcitation of charge carriers. In this work, we study the various processes that contribute to the generation of current in intraband (CB) photodetectors and build a method of investigation to reveal, among the different possibilities, the processes that actually result in electron emission in a particular device. After establishing a methodology, we apply it to a case study, more specifically, a dot-in-a-well (DWELL) photodetector with absorption peaks in the mid-infrared. By comparing absorption and photocurrent FTIR spectra as well as oscillator strength calculations performed by a computer simulation of the structure, we have approached the optical transitions and electron transport processes involved in the device s photoconductivity.

[pt] FOTODETECTORES

[en] PHOTODETECTORS

[pt] INFRAVERMELHO

[en] INFRARED

[pt] SEMICONDUTORES

[en] SEMICONDUCTORS

[pt] NANODISPOSITIVOS

[pt] INTRABANDA

[pt] QDIP

[pt] DWELL

Solution-Processed Optoelectronic Devices Based on Colloidal Semiconductor Nanostructures for Photodetection

Ivan, Jebakumar, D S

January 2015

Miniaturisation of electronic and optoelectronic devices have enabled the realization of system-on-a-chip technology in modern image sensors, where the photo sensor arrays and the corresponding signal processing circuitry are monolithically integrated in a single chip. Apart from intrinsic advantages, the drive towards miniaturisation has been further fuelled by the exotic properties exhibited by semiconductor materials at the nano scale. As the dimension of the material is gradually reduced from the bulk, interesting physical and chemical properties begin to emerge owing to the increased confinement of charge carriers in different spatial dimensions. Solution-processed optoelectronics have revolutionised the field of device physics over recent years due to the superior performance, ease of processing, substrate flexibility, cost-effective production of large-area devices and other advantages associated with the technique. In the present work, solution-processed photo detectors have been fabricated on SiO2/Si substrate facilitating the ease of integration with conventional silicon CMOS technology. The present thesis deals with the successful exploitation of most common point defects in semiconductor nanostructures to reduce the overlap of hole wave function with the envelop wave function of the ground state electron to improve photoconduction. As a result of the investigation process, successful strategies have been devised for the improvement of photoconduction by engineering the defect states. In the first study, the intrinsic copper vacancies and the capping agent thiol have been employed to trap photo holes in photo detectors based on copper indium selenide nanoparticles, thereby allowing the photoelectrons to transit the device. In the second study, the optical excitation of charge carriers into the defect-related band originating from oxygen vacancies further raises the photoconductivity of molybdenum trioxide nanobelts based photodetectors. In the third study, the absence of photoconductivity in zinc selenide based quantum dots has been attributed to the radiative recombination of photogenerated carriers at the donor-acceptor states caused by the self-compensation of point defects in the dots. In the final study, the crucial role of the energy depth of trap states in determining the carrier relaxation dynamics (temporal response) of the photodetector based on SnO2 nanowires has been discussed in detail. .

Optoelectronic Devices Semiconductor

Protoconductive Protoconduction

Photodetectors

Nanomaterials

CuInSe2 Nanoparticles

MoO3 Nanobelts

ZnSe Quantum Dots

SnO2 Nanowires

Materials Science

Síntese de nanofios de óxidos semicondutores para aplicações em dispositivos ópticos e eletrônicos /

Savu, Raluca.

January 2009

Resumo: A presente pesquisa teve como principal objetivo a obtenção de estruturas nanométricas de óxido de índio, óxido de estanho e óxido de zinco por evaporação térmica e síntese hidrotérmica e a construção e teste de sensores de gases e de fotodetectores de ultravioleta baseados nessas nanoestruturas. Foram realizados estudos da influência dos parâmetros experimentais das duas rotas de síntese usadas sobre as morfologias e as propriedades das estruturas. Para a obtenção das camadas nanoestruturadas por evaporação térmica foi especialmente construído um forno tubular que permitiu o controle da temperatura de deposição independente da temperatura de evaporação e da distância entre a fonte de evaporação e o substrato. Esses parâmetros, pouco explorados nas pesquisas reportadas na literatura, exerceram uma grande influência sobre a morfologia e as propriedades dos nanofios obtidos. O equipamento permitiu ainda um controle preciso da composição da atmosfera e da pressão de síntese. Na síntese química em solução, a construção de um reator hidrotérmico permitiu o estudo da influência da taxa de resfriamento sobre as dimensões, cristalinidade, morfologia e propriedades das nanoestruturas. Esse estudo, o primeiro do gênero na literatura, ressaltou a importância no controle deste parâmetro para sintetizar estruturas com propriedades melhoradas. As demais variáveis estudadas foram: a concentração das soluções, as camadas catalisadoras, a temperatura e o tempo de síntese. Foram testadas duas estratégias para a obtenção dos filmes nanoestruturados: spin-coating de suspensões de nanoestruturas sobre substratos de silício oxidado ou o crescimento das mesmas, durante a síntese, sobre substratos com camadas catalisadoras de zinco. Os nanofios e as camadas funcionais foram caracterizados por Difração de Raios-X (DRX), Microscopia Eletrônica de Varredura... (Resumo completo, clicar acesso eletrônico abaixo) / Abstract: The subject of this thesis covers the synthesis and growth of indium, tin and zinc oxide nanostructures by thermal evaporation and hydrothermal synthesis and the fabrication and testing of gas sensors and ultraviolet photodetectors based on these nanosized structures. For both chemical and physical routes, the influence of processing conditions over the morphology, dimensions and electrical properties of the nanowires was investigated. In order to obtain nanostructured layers by thermal evaporation a tubular furnace was specifically builti, allowed the control of the source-substrate distance and the deposition temperature independently of the evaporation one. These parameters, slightly explored in the literature, granted a big influence over the nanowires morphology and properties. Moreover, the equipment permitted the control of deposition atmosphere and pressure. The design and assembly of a hydrothermal reactor allowed studying the influence of the cooling rate over the dimension, morphology, cristallinity and, consequently, the properties of the nanostructures. This study highlighted the importance of controlling this particular parameter in the hydrothermal process, yielding nanostructured materials with enhanced properties. Variables such as solution concentration, synthesis temperature and time, surfanctants and precursors were also explored in the hydrothermal process. In order to obtain nanostructured thin films using the chemical bath deposition, two processing techniques were employed: spin-coating of powder suspensions over oxidized silicon substrates and nanostructured anisotropic growth directly from solution using zinc coated substrates. The nanowires and the functional nanostructured layers were characterized by X-Ray Diffraction (XRD), Field Emission Scanning Electron Microscopy (FE - SEM), Transmission Electron Microscopy (TEM) and X-ray Photoelectron Spectroscopy (XPS)... (Complete abstract click electronic access below) / Orientador: Maria Aparecida Zaghete Bertochi / Coorientador: Elson Longo / Banca: Antonio Ricardo Zanatta / Banca: Mônica Alonso Cotta / Banca: Talita Mazon Anselmo / Banca: Sidney José Lima Ribeiro / O Programa de Pós-Graduação em Ciência e Tecnologia de Materiais, PosMat, tem caráter institucional e integra as atividades de pesquisa em materiais de diversos campi da Unesp / Doutor

Nanoestrutura.

Detectores.

Nanostructures. eng

Semiconducting oxides. eng

Thermal evaporation eng

Hydrothermal synthesis. eng

Gas sensors. eng

Ultraviolet photodetectors. eng.

Fotodetectores de radiação infravermelha baseados em pontos quânticos de submonocamada / Infrared photodetectors based on submonolayer quantum dots.

Ahmad Al Zeidan

03 October 2017

Nesse trabalho, foi investigado um novo tipo de fotodetector de radiação infravermelha baseado em pontos quânticos de submonocamada de InAs obtidos pela técnica de epitaxia por feixe molecular (MBE, Molecular Beam Epitaxy). Suas propriedades foram comparadas com as de fotodetectores de pontos quânticos de InAs convencionais obtidos pela mesma técnica de deposição, mas no modo de crescimento Stranski-Krastanov. Medidas de corrente de escuro, de ruído, de responsividade e de absorção mostraram que, dependendo da estrutura das amostras, os dispositivos com pontos quânticos de submonocamada podem ter um excelente desempenho. / In this work, we investigated a new type of infrared photodetector based on InAs sub-monolayer quantum dots grown by molecular beam epitaxy (MBE). Their properties were compared with those of photodetectors containing conventional InAs quantum dots obtained by the same deposition technique, but in the Stranski-Krastanov growth mode. Dark current, noise, responsivity and absorption measurements have shown that, depending on the structure of the samples, the devices with sub-monolayer quantum dots can perform very well.

Epitaxia por feixes moleculares.

Fotodetectores

InAs

infravermelho

Pontos quânticos

Submonocamada

InAs

Infrared

Molecular beam epitaxy

Photodetectors

Quantum dots

Submonolayer