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Growth and characterization of two-dimensional III-V semiconductor platforms for mesoscopic physics and quantum devicesSaeed Fallahi (7012838) 13 August 2019 (has links)
<div>Achievements in the growth of ultra-pure III-V semiconductor materials using state of the art molecular beam epitaxy (MBE) machine has led to the discovery of new physics and technological innovations. High mobility two-dimensional electron gas (2DEG) embedded in GaAs/Al<sub>x</sub>Ga<sub>1−x</sub>As heterostructures provides an unparalleled platform for many-body physics including fractional quantum Hall effect. On the other hand, single electron devices fabricated on modulation doped GaAs/Al<sub>x</sub>Ga<sub>1−x</sub>As heterostructures have been extensively used for fabrication of quantum devices such as spin qubit with application in quantum computing. Furthermore, epitaxial hybrid superconductor-semiconductor heterostructures with ultra clean superconductor-semiconductor interface have been grown using MBE technique to explore rare physical quantum state of the matter namely Majorana zero modes with non-abelian exchange statistics.</div><div><br></div><div><div>Chapter 1 in the manuscript starts with description of GaAs MBE system at Purdue University and continues with the modifications have been made to MBE hardware and growth conditions for growing heterostrcutures with 2DEG mobility exceeding 35 × 10<sup>6</sup> cm<sup>−2</sup>/V s. Utilizing an ultra-high pure Ga source material and its further purification by thermal evaporation in the vacuum are determined to have major impact on growth of high mobility GaAs/Al<sub>x</sub>Ga<sub>1−x</sub>As heterostructures.</div></div><div><br></div><div>Chapter 2 reports a systematic study on the effect of silicon doping density on low
frequency charge noise and conductance drift in laterally gated nanostructures fabricated on modulation doped GaAs/Al<sub>x</sub>Ga<sub>1−x</sub>As heterostructures grown by Molecular Beam Epitaxy (MBE). The primary result of this study is that both charge noise
and conductance drift are strongly impacted by the silicon doping used to create the
two-dimensional electron gas. These findings shed light on the physical origin of the
defect states responsible for charge noise and conductance drift. This is especially
significant for spin qubit devices, which require minimization of conductance drift
and charge noise for stable operation and good coherence.
<br></div><div><br></div><div>Chapter 3 demonstrates measurements of the induced superconducting gap in
2D hybrid Al/Al<sub>0.15</sub>In<sub>0.85</sub>As/InAs heterostructures which is a promising platform for
scaling topological qubits based on Majorana zero modes. The 2DEG lies in an InAs
quantum well and is separated from the epitaxial Al layer by a barrier of Al<sub>0.15</sub>In<sub>0.85</sub>As
with thickness d. Due to hybridization between the wave functions of 2DEG and superconductor, the strength of induced gap in the 2DEG largely depends on the barrier
thickness. This chapter presents a systematic study of the strength of the induced
gap in hybrid Al/Al<sub>0.15</sub>In<sub>0.85</sub>As/InAs superconductor/semiconductor heterostructures
as a function of barrier thickness.<br></div><div><br></div><div><br></div>
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IMPURITY CONTROL AND ANALYSIS OF ULTRA-PURE GALLIUM FOR INCREASING MOBILITY IN GALLIUM ARSENIDE GROWN BY MOLECULAR BEAM EPITAXYKyungjean Min (6635897) 14 May 2019 (has links)
<p></p><p>High mobility 2DEG (two-dimensional
electron gas) confined in GaAs is a good platform to understand correlated
electron systems and a promising candidate for qubit devices. For example, the
non-Abelian feature of Fractional Quantum Hall state enabling topological
quantum computation is only found in GaAs with high mobility. Theoretical
calculations have shown that the mobility is inversely proportional to
impurities in GaAs/AlGaAs heterstructures grown by Molecular Beam Epitaxy
(MBE). In recent MBE experiments, the source Ga was found to be more important
in the limitation of mobility than Al and As. A high mobility of 35 million cm<sup>2</sup>/Vs was recently
observed when an 8N Ga (total nominal impurity
concentration of ~10 ppb) source
was used compared to 25
million cm<sup>2</sup>/Vs for a 7N Ga source. In addition, significant mobility increase
was observed after in-situ distillation of the source Ga before growth. In
order to clarify the mechanism of how the distillation contributed to the Ga
purification, thus resulting in the mobility increase, the MBE in-situ
distillation was analyzed by molecular distillation theory. Evaporation
behavior of solvent Ga was analyzed including effects of evaporation from a
crucible with receding liquid depth.
Then impurity removal through molecular distillation was analyzed with
molecular evaporation kinetics. The remaining 7N and 8N Ga after in-situ MBE
distillation and growth were elementally analyzed by ICP-MS (Inductively
Coupled Plasma Mass Spectrometry) and compared with analyses of the starting 7N
and 8N Ga from same lots. Due to the
increased detection limit of ICP-MS in metal analysis, the concentrations of
most impurity elements reached the detection limit of ~1-10 ppb. However,
unusual high concentration of 690 ppb Ge was found in the 7N Ga, exceeding the
nominal concentration of 7N (100 ppb). Significant decrease in Ge concentration
was found in the comparison of initial ultra-pure Ga and remaining Ga for both
grades of 7N and 8N. The significant Ge losses cannot be explained by atomic Ge
evaporation due to the low vapor pressure of Ge. However, a hypothesis of Ge evaporation as
GeO(g) by Ge active oxidation was proposed. In order to test the active
oxidation of very dilute Ge in Ga in the MBE conditions with very low P(O<sub>2</sub>),
the equilibrium P(GeO)-P(O<sub>2</sub>) vapor species diagram was calculated
from thermodynamics. The analysis shows
that even very dilute Ge in Ga of ~ 1 ppm concentration can be <a>actively oxidized in the extremely low P(O<sub>2</sub>) of
MBE</a>. In order to prove active oxidation of Ge, molecular distillation of 7N
Ga was performed in <a>a specially constructed high vacuum
chamber. The 7N Ga with unusual high Ge concentration of 440 ppb (by GDMS
analysis) was distilled for 16 h at 1360 K under the starting P(O<sub>2</sub>)
of 3 x 10<sup>-6</sup> torr and the total pressure of 10<sup>-5</sup> torr. The
chamber vacuum was monitored by Residual Gas Analyzer (RGA) and the residual Ga
after 16 h distillation was analyzed by GDMS. In the GDMS analysis, significant
Ge loss was found from 440 ppb to below the detection limit of 10 ppb,
confirming Ge active oxidation hypothesis. The oxygen-assisted impurity removal
in distillation also may be applicable to other impurities with high vapor
pressure gaseous oxide, but low vapor pressure itself, such as Al, Si and Sn. </a></p><br><p></p>
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Development of Low-Temperature Epitaxial Silicon Films and Application to Solar CellsEl Gohary, Hassan Gad El Hak Mohamed January 2010 (has links)
Solar photovoltaic has become one of the potential solutions for current energy needs and for combating greenhouse gas emissions. The photovoltaics (PV) industry is booming, with a yearly growth rate well in excess of 30% over the last decade. This explosive growth has been driven by market development programs to accelerate the deployment of sustainable energy options and rapidly increasing fossil fuel prices. Currently, the PV market is based on silicon wafer solar cells (thick cells of around 150–300 μm made of crystalline silicon). This technology, classified as the first-generation of photovoltaic cells. The second generation of photovoltaic materials is based on the introduction of thin film layers of semiconductor materials. Unfortunately, the conversion efficiency of the current PV systems is low despite the lower manufacturing costs. Nevertheless, to achieve highly efficient silicon solar cell devices, the development of new high quality materials in terms of structure and electrical properties is a must to overcome the issues related to amorphous silicon (a -Si:H) degradation. Meanwhile, to remain competitive with the conventional energy sources, cost must be taken into consideration. Moreover, novel approaches combined with conventional mature silicon solar cell technology can boost the conventional efficiency and break its maximum limits. In our approach, we set to achieve efficient, stable and affordable silicon solar cell devices by focusing on the development of a new device made of epitaxial films. This new device is developed using new epitaxial growth phosphorous and/or boron doped layers at low processing temperature using plasma enhanced chemical vapor deposition (PECVD). The junction between the phosphorous or boron-doped epitaxial film of the device is formed between the film and the p or n-type crystalline silicon (c-Si) substrate, giving rise to (n epi-Si/p c-Si device or p epi-Si/n c-Si device), respectively. Different processing conditions have been fully characterized and deployed for the fabrication of different silicon solar cells architectures. The high quality epitaxial film (up to 400 nm) was used as an emitter for an efficient stable homojunction solar cell. Extensive analysis of the developed fine structure material, using high resolution transmission electron microscope (HRTEM), showed that hydrogen played a crucial role in the epitaxial growth of highly phosphorous doped silicon films. The main processing parameters that influenced the quality of the structure were; radio frequency (RF) power density, the processing chamber pressure, the substrate temperature, the gas flow rate used for deposition of silicon films, and hydrogen dilution. The best result, in terms of structure and electrical properties, was achieved at intermediate hydrogen dilution (HD) regime between 91 and 92% under optimized deposition conditions of the rest of the processing parameters. The conductivity and the carrier mobility values are good indicators of the electrical quality of the silicon (Si) film and can be used to investigate the structural quality indirectly. The electrical conductivity analyses using spreading resistance profile (SRP), through the detection of active carriers inside the developed films, are presented in details for the developed epitaxial film under the optimized processing conditions. Measurements of the active phosphorous dopant revealed that, the film has a very high active carrier concentration of an average of 5.0 x1019 cm-3 with a maximum value of 6.9 x 1019 cm-3 at the interface between substrate and the epitaxial film. The observed higher concentration of electrically active P atoms compared to the total phosphorus concentration indicates that more than half of dopants become incorporated into substitutional positions. Highly doping efficiency ηd of more than 50 % was calculated from both secondary ion mass spectroscopy (SIMS) and SRP analysis. A variety of proposed structures were fabricated and characterized on planar, textured, and under different deposition temperatures. Detailed studies of the photovoltaic properties of the fabricated devices were carried out using epitaxial silicon films. The results of these studies confirmed that the measured open circuit voltage (Voc) of the device ranged between 575 and 580 mV with good fill factor (FF) values in the range of 74-76 %. We applied the rapid thermal process (RTP) for a very short time (60 s) at moderate temperature of 750oC to enhance the photovoltaic properties of the fabricated device. The following results were achieved, the values of Voc, and the short circuit current (Isc) were 598 mV and 27.5 mA respectively, with a fill factor value of up to 76 % leading to an efficiency of 12.5 %. Efficiency enhancement by 13.06 % was achieved over the reference cell which was prepared without using RTP. Another way to increase the efficiency of the fabricated device is to reduce the reflections from its polished substrate. This was achieved by utilizing the light trapping technique that transforms the reflective polished surface into a pyramidical texturing using alkaline solutions. Further enhancements of both Voc and Isc were achieved with values of 612 mV and 31mA respectively, and a fill factor of 76 % leading to an increase in the efficiency by up to 13.8 %. A noticeable efficiency enhancement by ~20 % over the reference cell is reported for the developed devices on the textured surfaces. Moreover, the efficiency of the fabricated epitaxial silicon solar cells can be boosted by the deployment of silicon nanocrystals (Si NCs) on the top surface of the fabricated devices. In the course of this PhD research we found a way to achieve this by depositing a thin layer of Si NCs, embedded in amorphous silicon matrix, on top of the epitaxial film. Structural analysis of the deposited Si NCs was performed. It is shown from the HRTEM analysis that the developed Si NCs, are randomly distributed, have a spherical shape with a radius of approximately 2.5 nm, and are 10-20 nm apart in the amorphous silicon matrix. Based on the size of the developed Si NCs, the optical band gap was found to be in the region of 1.8-2.2 eV. Due to the incorporation of Si NCs layer a noticeable enhancement in the Isc was reported.
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Development of Low-Temperature Epitaxial Silicon Films and Application to Solar CellsEl Gohary, Hassan Gad El Hak Mohamed January 2010 (has links)
Solar photovoltaic has become one of the potential solutions for current energy needs and for combating greenhouse gas emissions. The photovoltaics (PV) industry is booming, with a yearly growth rate well in excess of 30% over the last decade. This explosive growth has been driven by market development programs to accelerate the deployment of sustainable energy options and rapidly increasing fossil fuel prices. Currently, the PV market is based on silicon wafer solar cells (thick cells of around 150–300 μm made of crystalline silicon). This technology, classified as the first-generation of photovoltaic cells. The second generation of photovoltaic materials is based on the introduction of thin film layers of semiconductor materials. Unfortunately, the conversion efficiency of the current PV systems is low despite the lower manufacturing costs. Nevertheless, to achieve highly efficient silicon solar cell devices, the development of new high quality materials in terms of structure and electrical properties is a must to overcome the issues related to amorphous silicon (a -Si:H) degradation. Meanwhile, to remain competitive with the conventional energy sources, cost must be taken into consideration. Moreover, novel approaches combined with conventional mature silicon solar cell technology can boost the conventional efficiency and break its maximum limits. In our approach, we set to achieve efficient, stable and affordable silicon solar cell devices by focusing on the development of a new device made of epitaxial films. This new device is developed using new epitaxial growth phosphorous and/or boron doped layers at low processing temperature using plasma enhanced chemical vapor deposition (PECVD). The junction between the phosphorous or boron-doped epitaxial film of the device is formed between the film and the p or n-type crystalline silicon (c-Si) substrate, giving rise to (n epi-Si/p c-Si device or p epi-Si/n c-Si device), respectively. Different processing conditions have been fully characterized and deployed for the fabrication of different silicon solar cells architectures. The high quality epitaxial film (up to 400 nm) was used as an emitter for an efficient stable homojunction solar cell. Extensive analysis of the developed fine structure material, using high resolution transmission electron microscope (HRTEM), showed that hydrogen played a crucial role in the epitaxial growth of highly phosphorous doped silicon films. The main processing parameters that influenced the quality of the structure were; radio frequency (RF) power density, the processing chamber pressure, the substrate temperature, the gas flow rate used for deposition of silicon films, and hydrogen dilution. The best result, in terms of structure and electrical properties, was achieved at intermediate hydrogen dilution (HD) regime between 91 and 92% under optimized deposition conditions of the rest of the processing parameters. The conductivity and the carrier mobility values are good indicators of the electrical quality of the silicon (Si) film and can be used to investigate the structural quality indirectly. The electrical conductivity analyses using spreading resistance profile (SRP), through the detection of active carriers inside the developed films, are presented in details for the developed epitaxial film under the optimized processing conditions. Measurements of the active phosphorous dopant revealed that, the film has a very high active carrier concentration of an average of 5.0 x1019 cm-3 with a maximum value of 6.9 x 1019 cm-3 at the interface between substrate and the epitaxial film. The observed higher concentration of electrically active P atoms compared to the total phosphorus concentration indicates that more than half of dopants become incorporated into substitutional positions. Highly doping efficiency ηd of more than 50 % was calculated from both secondary ion mass spectroscopy (SIMS) and SRP analysis. A variety of proposed structures were fabricated and characterized on planar, textured, and under different deposition temperatures. Detailed studies of the photovoltaic properties of the fabricated devices were carried out using epitaxial silicon films. The results of these studies confirmed that the measured open circuit voltage (Voc) of the device ranged between 575 and 580 mV with good fill factor (FF) values in the range of 74-76 %. We applied the rapid thermal process (RTP) for a very short time (60 s) at moderate temperature of 750oC to enhance the photovoltaic properties of the fabricated device. The following results were achieved, the values of Voc, and the short circuit current (Isc) were 598 mV and 27.5 mA respectively, with a fill factor value of up to 76 % leading to an efficiency of 12.5 %. Efficiency enhancement by 13.06 % was achieved over the reference cell which was prepared without using RTP. Another way to increase the efficiency of the fabricated device is to reduce the reflections from its polished substrate. This was achieved by utilizing the light trapping technique that transforms the reflective polished surface into a pyramidical texturing using alkaline solutions. Further enhancements of both Voc and Isc were achieved with values of 612 mV and 31mA respectively, and a fill factor of 76 % leading to an increase in the efficiency by up to 13.8 %. A noticeable efficiency enhancement by ~20 % over the reference cell is reported for the developed devices on the textured surfaces. Moreover, the efficiency of the fabricated epitaxial silicon solar cells can be boosted by the deployment of silicon nanocrystals (Si NCs) on the top surface of the fabricated devices. In the course of this PhD research we found a way to achieve this by depositing a thin layer of Si NCs, embedded in amorphous silicon matrix, on top of the epitaxial film. Structural analysis of the deposited Si NCs was performed. It is shown from the HRTEM analysis that the developed Si NCs, are randomly distributed, have a spherical shape with a radius of approximately 2.5 nm, and are 10-20 nm apart in the amorphous silicon matrix. Based on the size of the developed Si NCs, the optical band gap was found to be in the region of 1.8-2.2 eV. Due to the incorporation of Si NCs layer a noticeable enhancement in the Isc was reported.
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Projeto e construção de um sistema de crescimento epitaxial por feixe molecular / Project and construction of a molecular beam epitaxy growth systemGomes, Joaquim Pinto 29 May 2009 (has links)
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Previous issue date: 2009-05-29 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / The epitaxial growth technique by molecular beams (Molecular Beam Epitaxy – MBE) can be considered as one of the most important for obtaining thin fine films, heterostructures and nanostructures nowadays, allowing the production of high quality layers, and it also allows the in situ monitoring of process through several techniques of characterization. This work presents the project, the construction and the initial tests of a MBE system for the growing of compounds containing cadmium, tellurium, manganese and zinc. The work shows a bibliographic revision of the main types of epitaxy, some of the main techniques of growth, the basic principles of vacuum technology and the necessary tools to the construction of the system. The detailed project of the system and its main components represented. Finally, the functioning tests of the vacuum systems, the effusion cells, the system of controlling and automation and the results obtained with the first obtained samples represented. The total cost of the system in the current configuration is approximately R$150.000 which is about as less as one fourth of one commercial system with approximately the same characteristics. / A técnica de crescimento epitaxial por feixes moleculares (Molecular Beam Epitaxy – MBE) pode ser considerada como uma das mais importantes para a obtenção de filmes finos, heteroestruturas e nanoestruturas nos dias atuais, permitindo a obtenção de filmes de excelente qualidade, além de permitir o acompanhamento do crescimento in situ através de diversas técnicas de caracterização. Este trabalho aborda o projeto, a construção e os testes iniciais de um sistema de MBE para o crescimento de compostos contendo Cádmio, Telúrio, Manganês e Zinco. O trabalho apresenta uma revisão bibliográfica dos principais tipos de epitaxia, algumas das principais técnicas de crescimento, princípios básicos da tecnologia de vácuo e os instrumentos necessários à construção do sistema. É apresentado o projeto detalhado do sistema e seus principais componentes. Finalmente, descrevem-se os testes de funcionamento do sistema de vácuo, das células de efusão, o sistema de controle e automatização e os resultados obtidos com as primeiras amostras obtidas. O custo total do sistema na configuração atual é de aproximadamente R$ 150.000, cerca de 4 vezes menor que o de um sistema comercial com aproximadamente as mesmas características.
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Rasterkraftmikroskopie an dünnen organischen und metall/organischen Schichten auf SiliziumoxidReiniger, Michael 18 May 2001 (has links)
Diese Arbeit beschäftigt sich mit der Herstellung von organischen selbstorganisierenden (Sub-)Monolagen (sog. SAM s) auf Siliziumoxid und deren Metallisierung. Die characteristischen Strukturen dieser Oberflächen sind mit der Rasterkraftmikroskopie (RKM) untersucht worden. Im präparativen Abschnitt wird die Abscheidung des SAM (Octadecyltrichlorosilan (OTS)) in einer Toluol/Wasserlösung auf eine Siliziumoxidoberfläche und deren anschließendem lateralen Erscheinungsbild (als Octadecylsiloxan ODS) beschrieben. Die Submonolagen des ODS auf dem Oxid erscheinen in den Topografiebildern des RKM s als eine Art Insellandschaft . Diese Modellstrukturen mit stark unterschiedlicher Oberflächeneigenschaften sind in dem methodischen Teil der Arbeit unter verschiedenen äußeren Bedingungen untersucht worden. Neben der Lateralkraft (Kontakt-Modus) und der Dämpfung (dyn. Nichtkontakt-Modus) stand hier die Kontrastentstehung der Topografie im RKM im Vordergrund. Im Gegensatz zu der theoretischen Länge des ODS-Moleküls wurde eine geringere Höhe des adsorbierten Moleküls gemessen. Im zweiten Teil dieser Arbeit wurde untersucht, wie die ODS-(Unter)Struktur das Wachstum aufgedampfter Metallschichten beeinflusst. Die Ergebnisse der Evaporation mit Silber und Eisen ergaben zum Teil überraschende Ergebnisse. Frisch aufgedampfte Filme ließen die Unterstruktur anhand der Größe der Metallcluster erkennen, wobei das Silber auf ODS größere Cluster bildete als Eisen auf ODS. Nach einer Temperaturbehandlung unterscheiden sich die Systeme sehr stark, im Falle des Fe-Substrates invertierte sich der Kontrast der Topografie.
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