Global ETD Search

11	Incorporation d'azote et stabilité des polytypes de la croissance en phase gazeuse de monocristaux de SiC / Nitrogen incorporation and polytype stability of SiC single crystal growth from the vapor phase Tsavdaris, Nikolaos 06 January 2015 (has links) Le carbure de silicium est l'un des semi-conducteurs les plus importants et les plus répandus dans les appareils électroniques de puissance. Du fait de la demande croissante d'électronique à haut rendement, bas coût et économe en énergie, il est nécessaire d'améliorer les propriétés des semi-conducteurs monocristallins. Cela demande une meilleure compréhension des phénomènes impliqués dans le procédé de croissance de ces matériaux. Cette thèse présentera de nouvelles perspectives sur deux sujets majeurs dans le domaine de la croissance en phase gazeuse de monocristaux de SiC. Dans un premier temps, le procédé de croissance utilisé dans notre laboratoire a été développé dans le but d'améliorer la qualité et la taille des cristaux de SiC obtenus. Une géométrie permettant la croissance sans contact et reproductible de monocristaux de SiC a été obtenue. La nucléation et la propagation des instabilités structurelles (inclusions de polytype étranger) apparaissant lors de la croissance ont été étudiés de façon continue. Deux critères spécifiques doivent être réunis pour qu'un polytype étranger puisse nucléer. Une fois le point de nucléation localisé, la propagation du polytype étranger dans le volume du cristal peut être appréhendée. Lorsque la stabilisation et déstabilisation des polytypes de SiC ont été mieux comprises, une tentative a été faite pour stabiliser la croissance du polytype 15R-SiC. L'objectif final, les paramètres de croissance susceptibles de renforcer la croissance préférentielle de 15R-SiC, a été mis en évidence. Enfin, l'incorporation d'azote pendant la croissance en phase gazeuse de monocristaux a été étudiée. En effet, aucune description détaillée n'existe pour l'incorporation d'azote dans le SiC, bien que ce soit le dopant le plus couramment utilisé. Notre contribution à cet effort porte sur l'étude de la concentration d'azote dans les cristaux obtenus en fonction de différents paramètres de croissance. Compte tenu des mécanismes d'adsorption/désorption à la surface de croissance, un effort a été fait pour expliquer les tendances obtenues expérimentalement. / Silicon Carbide is one of the most important and widely used semiconductors for power electronic devices. Due to the increasing demand for high efficiency, low cost and energy saving electronics, further improvement of the properties of single crystal semiconductors is needed. That requires a better understanding of the phenomena involved in the growth process of these materials. This thesis will bring some new insight into two main topics at the field of SiC bulk growth from the vapor phase. Initially, the growth process used in our laboratory was developed in order to improve the quality and the size of the grown SiC crystal. A geometry that allows the contactless and reproducible growth of SiC single crystals was obtained. Continuously, we investigated the nucleation and propagation of structural instabilities (foreign polytype inclusions) that appear during growth. Two specific criteria must be fulfilled for a foreign polytype to be nucleated. Once the nucleation point is located, the propagation of the foreign polytype in the volume of the grown crystal can be comprehended. Once the stabilization or destabilization of the SiC polytypes was better perceived, an attempt was made to stabilize the growth of the 15R-SiC polytype. As a final objective, the growth parameters that could preferentially enhance the growth of the 15R-SiC are highlighted. Last, nitrogen incorporation during bulk growth from the vapor phase was studied. Indeed as the most commonly used dopant, no full description exists for the incorporation of nitrogen in SiC. We contribute to this effort by exploring the nitrogen concentration in the grown crystals as a function of various growth parameters. Considering the adsorption/desorption mechanisms at the growing surface, effort was given to explain the experimentally obtained trends. Cristallogenese Physical vapor transport Dopage SiC Azote Polytype Crystal growth Physical vapor transport Doping SiC Nitrogen Polytype 620
12	Incorporation d'azote et stabilité des polytypes de la croissance en phase gazeuse de monocristaux de SiC / Nitrogen incorporation and polytype stability of SiC single crystal growth from the vapor phase Tsavdaris, Nikolaos 06 January 2015 (has links) Le carbure de silicium est l'un des semi-conducteurs les plus importants et les plus répandus dans les appareils électroniques de puissance. Du fait de la demande croissante d'électronique à haut rendement, bas coût et économe en énergie, il est nécessaire d'améliorer les propriétés des semi-conducteurs monocristallins. Cela demande une meilleure compréhension des phénomènes impliqués dans le procédé de croissance de ces matériaux. Cette thèse présentera de nouvelles perspectives sur deux sujets majeurs dans le domaine de la croissance en phase gazeuse de monocristaux de SiC. Dans un premier temps, le procédé de croissance utilisé dans notre laboratoire a été développé dans le but d'améliorer la qualité et la taille des cristaux de SiC obtenus. Une géométrie permettant la croissance sans contact et reproductible de monocristaux de SiC a été obtenue. La nucléation et la propagation des instabilités structurelles (inclusions de polytype étranger) apparaissant lors de la croissance ont été étudiés de façon continue. Deux critères spécifiques doivent être réunis pour qu'un polytype étranger puisse nucléer. Une fois le point de nucléation localisé, la propagation du polytype étranger dans le volume du cristal peut être appréhendée. Lorsque la stabilisation et déstabilisation des polytypes de SiC ont été mieux comprises, une tentative a été faite pour stabiliser la croissance du polytype 15R-SiC. L'objectif final, les paramètres de croissance susceptibles de renforcer la croissance préférentielle de 15R-SiC, a été mis en évidence. Enfin, l'incorporation d'azote pendant la croissance en phase gazeuse de monocristaux a été étudiée. En effet, aucune description détaillée n'existe pour l'incorporation d'azote dans le SiC, bien que ce soit le dopant le plus couramment utilisé. Notre contribution à cet effort porte sur l'étude de la concentration d'azote dans les cristaux obtenus en fonction de différents paramètres de croissance. Compte tenu des mécanismes d'adsorption/désorption à la surface de croissance, un effort a été fait pour expliquer les tendances obtenues expérimentalement. / Silicon Carbide is one of the most important and widely used semiconductors for power electronic devices. Due to the increasing demand for high efficiency, low cost and energy saving electronics, further improvement of the properties of single crystal semiconductors is needed. That requires a better understanding of the phenomena involved in the growth process of these materials. This thesis will bring some new insight into two main topics at the field of SiC bulk growth from the vapor phase. Initially, the growth process used in our laboratory was developed in order to improve the quality and the size of the grown SiC crystal. A geometry that allows the contactless and reproducible growth of SiC single crystals was obtained. Continuously, we investigated the nucleation and propagation of structural instabilities (foreign polytype inclusions) that appear during growth. Two specific criteria must be fulfilled for a foreign polytype to be nucleated. Once the nucleation point is located, the propagation of the foreign polytype in the volume of the grown crystal can be comprehended. Once the stabilization or destabilization of the SiC polytypes was better perceived, an attempt was made to stabilize the growth of the 15R-SiC polytype. As a final objective, the growth parameters that could preferentially enhance the growth of the 15R-SiC are highlighted. Last, nitrogen incorporation during bulk growth from the vapor phase was studied. Indeed as the most commonly used dopant, no full description exists for the incorporation of nitrogen in SiC. We contribute to this effort by exploring the nitrogen concentration in the grown crystals as a function of various growth parameters. Considering the adsorption/desorption mechanisms at the growing surface, effort was given to explain the experimentally obtained trends. Cristallogenese Physical vapor transport Dopage SiC Azote Polytype Crystal growth Physical vapor transport Doping SiC Nitrogen Polytype 620
13	On the Hydroclimate of Southern South America: Water Vapor Transport and the Role of Shallow Groundwater on Land-Atmosphere Interactions Martinez Agudelo, John Alejandro January 2015 (has links) The present work focuses on the sources and transport of water vapor to the La Plata Basin (LPB), and the role of groundwater dynamics on the simulation of hydrometeorological conditions over the basin. In the first part of the study an extension to the Dynamic Recycling Model (DRM) is developed to estimate the water vapor transported to the LPB from different regions in South America and the nearby oceans, and the corresponding contribution to precipitation over the LPB. It is found that more than 23% of the precipitation over the LPB is from local origin, while nearly 20% originates from evapotranspiration from the southern Amazon. Most of the moisture comes from terrestrial sources, with the South American continent contributing more than 62% of the moisture for precipitation over the LPB. The Amazonian contribution increases during the positive phase of El Niño and the negative phase of the Antarctic Oscillation. In the second part of the study the effect of a groundwater scheme on the simulation of terrestrial water storage, soil moisture and evapotranspiration (ET) over the LPB is investigated. It is found that the groundwater scheme improves the simulation of fluctuations in the terrestrial water storage over parts of the southern Amazon. There is also an increase in the soil moisture in the root zone over those regions where the water table is closer to the surface, including parts of the western and southern Amazon, and of the central and southern LPB. ET increases in the central and southern LPB, where it is water limited. Over parts of the southeastern Amazon the effects of the groundwater scheme are only observed at higher resolution, when the convergence of lateral groundwater flow in local topographical depressions is resolved by the model. Finally, the effects of the groundwater scheme on near surface conditions and precipitation are explored. It is found that the increase in ET induced by the groundwater scheme over parts of the LPB induces an increase in near surface specific humidity, accompanied by a decrease in near surface temperature. During the dry season, downstream of the regions where ET increases, there is also a slight increase in precipitation, over a region where the model has a dry bias compared with observations. During the early rainy season, there is also an increase in the local convective available potential energy. Over the southern LPB, groundwater induces an increase in ET and precipitation of 13 and 10%, respectively. Over the LPB, the groundwater scheme tends to improve the warm and dry biases of the model. It is suggested that a more realistic simulation of the water table depth could further increase the simulated precipitation during the early rainy season. Land-atmosphere interactions Land Surface Models South America Water Vapor Transport Atmospheric Sciences Hydrometeorology
14	Synthesis Of Germanium Nanowires By Vapor Transport And Fabrication Of Transparent And Flexible Photodetectors Aksoy, Burcu 01 July 2012 (has links) (PDF) Nanomaterials are widely investigated by researches and because of their unique properties they have been utilized in many different devices. Nanowires are one of these materials which show deviated mechanical, chemical, physical and optical, properties from their bulk counterparts. These deviations in properties of the nanowires are based on both their high surface to volume ratio and quantum confinement effect. Lately optical properties of nanowires have received great attention as they also exhibit good light sensitivity. Germanium is a semiconductor, which has been used widely as an active material in infrared light detectors. Due to excellent light detection of germanium its nanostructures have also been widely studied in optoelectronic devices. Germanium nanowires have been used in many devices such as field effect transistors, diodes, field emitters and photodetectors. Synthesis of high quality and high aspect ratio germanium nanowires could make important contributions to these devices. There are several synthesis methods for germanium nanowires. These are electrochemical etching, solvothermal, supercritical v fluidic, laser ablation, chemical vapor deposition and vapor transport methods. Among these methods, high quality, single crystalline, defect free germanium nanowires using accessible solid powder precursors could be synthesized with vapor transport method. In the first part of this thesis, germanium nanowire growth with vapor transport method is investigated. One of the most advantageous features of this method is using solid powder precursors instead of toxic gases. Until now, three different kinds of solid germanium precursors have been reported in vapor transport method, all of them are investigated and the resulting nanowires are compared in this thesis. Vapor transport method enables high control over the morphology of the nanowires. The most important parameters which affect the morphology of the nanowires are temperature, pressure and precursor type. Therefore, a detailed parametric study is provided based on these parameters and their effect on the final diameter of the nanowires is determined. The as &ndash / synthesized nanowires contain a very thick oxide layer on their surface. Therefore, oxide removal with acid etching is also investigated in this thesis. In the second part of this thesis, utilization of the germanium nanowire networks in fully transparent, flexible and network enhanced photodetectors is investigated. In order to obtain a germanium nanowire network, the as-synthesized nanowires are transferred from growth substrate to the device substrate by sonication and vacuum filtration. Silver nanowires and single walled carbon nanotubes are used as fully transparent electrodes. Both rigid and flexible photodetectors are fabricated and their current-voltage characteristics and photoresponse behaviors with different germanium nanowire densities are determined. QD Nonmetals 161-169
15	Meridional advection of moisture in the Arctic. Boyes, G. A. January 1963 (has links) The present study contains a calculation and discussion of meridional advection of water vapour on a daily basis across three latitude circles (65°N., 70°N., 80°N.) for the months of January and July, 1958. [...] Meteorology. Water vapor transport -- Arctic regions.
16	Structural analysis of airborne flux traces and their link to remote sensing of vegetation and surface temperature Caramori, Paulo Henrique January 1992 (has links) This thesis examines the link between airborne flux estimates of CO$ sb2$, sensible heat, and water vapor, and surface parameters retrieved by remote sensing. Chapter 1 analyses the relationship between surface temperature and vegetation indices, obtained from the Advanced Very High Resolution Radiometer on board of NOAA-9 and -10 satellites, and fluxes of sensible heat, latent heat, and CO$ sb2$, estimated from aircraft. Linear relationships between CO$ sb2$ and the Normalized Difference Vegetation Index (NDVI) or the Simple Ratio vegetation index (SR) are found on a daily basis, but a highly nonlinear relationship appears for the seasonal variation. Latent Heat fluxes showed the poorest correlations with surface parameters. A seasonal linear relationship appeared between sensible heat and NDVI. Local extreme flux values due to the intermittency of boundary layer dynamics largely contribute to lower the correlations; such variations are the reason for the difficulties in relating fluxes obtained from single overpasses and over short distances to fixed points at the surface. This problem is further examined in Chapter 2, in which conditional sampling of airborne flux estimates is used to characterize the turbulent structures that are carrying flux, and their link to the surface. The analysis confirms that few extreme events may carry a significant fraction of the flux. Missing or hitting one of these structures may translate into very large oscillations on the flux estimate that are often not directly coupled to surface characteristics. A much clearer surface 'signature' emerges when measurements are taken within the surface layer, since the reorganization of turbulent structures that takes place with increasing height will result in a merging of the signature that came from different sources at the surface. This helps to explain some of the poor correlations obtained in Chapter 1 and reinforces the need for a better understanding of the distributions of these tu Water vapor transport. Terrestrial heat flow. Atmospheric carbon dioxide. Eddy flux. Remote sensing.
17	Synthesis, Characterization, and Application of Hollow Carbon Nanostructures January 2016 (has links) abstract: This dissertation describes fundamental studies of hollow carbon nanostructures, which may be used as electrodes for practical energy storage applications such as batteries or supercapacitors. Electron microscopy is heavily utilized for the nanoscale characterization. To control the morphology of hollow carbon nanostructures, ZnO nanowires serve as sacrificial templates. The first part of this dissertation focuses on the optimization of synthesis parameters and the scale-up production of ZnO nanowires by vapor transport method. Uniform ZnO nanowires with 40 nm width can be produced by using 1100 °C reaction temperature and 20 sccm oxygen flow rate, which are the two most important parameters. The use of ethanol as carbon source with or without water steam provides uniform carbonaceous deposition on ZnO nanowire templates. The amount of as-deposited carbonaceous material can be controlled by reaction temperature and reaction time. Due to the catalytic property of ZnO surface, the thicknesses of carbonaceous layers are typically in nanometers. Different methods to remove the ZnO templates are explored, of which hydrogen reduction at temperatures higher than 700 °C is most efficient. The ZnO templates can also be removed under ethanol environment, but the temperatures need to be higher than 850 °C for practical use. Characterizations of hollow carbon nanofibers show that the hollow carbon nanostructures have a high specific surface area (>1100 m2/g) with the presence of mesopores (~3.5 nm). The initial data on energy storage as electrodes of electrochemical double layer capacitors show that high specific capacitance (> 220 F/g) can be obtained, which is related to the high surface area and unique porous hollow structure with a thin wall. / Dissertation/Thesis / Doctoral Dissertation Physics 2016 Nanoscience Nanotechnology Materials Science Carbon Hollow Nanowire Supercapacitor Vapor Transport ZnO
18	Angle Resolved Polarization and Vibrational Studies of Transition Metal Trichalcogenides and Related Alloys January 2017 (has links) abstract: A new class of layered materials called the transition metal trichalcogenides (TMTCs) exhibit strong anisotropic properties due to their quasi-1D nature. These 2D materials are composed of chain-like structures which are weakly bound to form planar sheets with highly directional properties. The vibrational properties of three materials from the TMTC family, specifically TiS3, ZrS3, and HfS3, are relatively unknown and studies performed in this work elucidates the origin of their Raman characteristics. The crystals were synthesized through chemical vapor transport prior to mechanical exfoliation onto Si/SiO¬2 substrates. XRD, AFM, and Raman spectroscopy were used to determine the crystallinity, thickness, and chemical signature of the exfoliated crystals. Vibrational modes and anisotropic polarization are investigated through density functional theory calculations and angle-resolved Raman spectroscopy. Particular Raman modes are explored in order to correlate select peaks to the b-axis crystalline direction. Mode III vibrations for TiS3, ZrS3, and HfS3 are shared between each material and serves as a unique identifier of the crystalline orientation in MX3 materials. Similar angle-resolved Raman studies were conducted on the novel Nb0.5Ti0.5S3 alloy material grown through chemical vapor transport. Results show that the anisotropy direction is more difficult to determine due to the randomization of quasi-1D chains caused by defects that are common in 2D alloys. This work provides a fundamental understanding of the vibrational properties of various TMTC materials which is needed to realize applications in direction dependent polarization and linear dichroism. / Dissertation/Thesis / Masters Thesis Materials Science and Engineering 2017 Materials Science Nanoscience Engineering 2D Materials Anisotropic Materials Chemical Vapor Transport Raman Spectroscopy Transition Metal Trichalcogonides
19	Untersuchungen zu Gasphasentransporten in quasibinären Systemen von Bi2Se3 mit Bi2Te3, Sb2Se3, MnSe und FeSe zur Erzeugung von Nanokristallen Nowka, Christian 16 January 2017 (has links) (PDF) In Topologischen Isolatoren (TI) werden metallische Zustände an der Oberfläche beobachtet, während die entsprechenden Volumenzustände eine Bandlücke aufweisen. Der Volumenbeitrag zur Leitfähigkeit von TI-Materialien macht eine Synthese von Nanokristallen bzw. eine Dotierung nötig. Der Fokus der Untersuchungen dieser Arbeit liegt dabei auf der Erzeugung von Nanokristallen der TI-Materialien Bi2Te3- und Bi2Te2Se sowie dotierter Bi2Se3-Nanokristallen. Die Synthese der Nanokristalle erfolgte durch den Gasphasentransport im geschlossenen System über den Mechanismus einer Zersetzungssublimation bzw. unter dem Einsatz eines Transportmittels. Für eine erfolgreiche Erzeugung der Nanokristalle sind im Vorfeld thermodynamische Modellierungen des Gasphasentransports sowie Versuche zum chemischen Transport für die quasibinären Systeme Bi2Se3-Bi2Te3, Bi2Se3-Sb2Se3 und Bi2Se3-FeSe sowie für das ternäre System Mn-Bi-Se durchgeführt worden. Durch Versuche zum chemischen Transport konnten die Aussagen der Modellierung bestätigt und im Weiteren der Dotandengehalt in den abgeschiedenen Kristallen sowie der Einlagerungsmechanismus durch Ergebnisse aus XRD- und ICP-OES-Untersuchungen beschrieben werden. Die Synthese bzw. Dotierung der Nanokristalle wurde hauptsächlich durch die Transportrate und den Dampfdruck des Dotanden bestimmt. In den Systemen Bi2Se3-Bi2Te3 und Bi2Se3-Sb2Se3 ist ein Gasphasentransport über eine Zersetzungssublimation durchführbar und resultierte in einer erfolgreichen Darstellung von Bi2Te3- und Bi2Te2Se-Nanokristallen sowie von dotierten (SbxBi1-x)2Se3-Nanokristallen. Entgegen dessen erfolgte der Gasphasentransport in den Systemen Bi2Se3-FeSe und Mn-Bi-Se unter Verwendung eines Transportmittels. Hierbei verringerten die gesteigerten Transportraten das Wachtum von Nanokristallen. Im Weiteren gelang es dotierte (Fe,Mn)xBi2-xSe3-Volumenkristalle sowie MnBi2Se4-Einkristalle darzustellen und mittels XRD, ICP-OES, magnetischer Messungen sowie elektrischem Transport zu charakterisieren. Chemischer Transport Topologische Isolatoren Bi2Se3 chemical vapor transport topological insulators Bi2Se3 ddc:540 rvk:VE 5907
20	Engineering Properties of Transition Metal Halides via Cationic Alloying January 2020 (has links) abstract: Transition metal di- and tri-halides (TMH) have recently gathered research attention owing to their intrinsic magnetism all the way down to their two-dimensional limit. 2D magnets, despite being a crucial component for realizing van der Waals heterostructures and devices with various functionalities, were not experimentally proven until very recently in 2017. The findings opened up enormous possibilities for studying new quantum states of matter that can enable potential to design spintronic, magnetic memory, data storage, sensing, and topological devices. However, practical applications in modern technologies demand materials with various physical and chemical properties such as electronic, optical, structural, catalytic, magnetic etc., which cannot be found within single material systems. Considering that compositional modifications in 2D systems lead to significant changes in properties due to the high anisotropy inherent to their crystallographic structure, this work focuses on alloying of TMH compounds to explore the potentials for tuning their properties. In this thesis, the ternary cation alloys of Co(1-x)Ni(x)Cl(2) and Mo(1-x)Cr(x)Cl(3) were synthesized via chemical vapor transport at a various stoichiometry. Their compositional, structural, and magnetic properties were studied using Energy Dispersive Spectroscopy, Raman Spectroscopy, X-Ray Diffraction, and Vibrating Sample Magnetometry. It was found that completely miscible ternary alloys of Co(1-x)Ni(x)Cl(2) show an increasing Néel temperature with nickel concentration. The Mo(1-x)Cr(x)Cl(3) alloy shows potential magnetic phase changes induced by the incorporation of molybdenum species within the host CrCl3 lattice. Magnetic measurements give insight into potential antiferromagnetic to ferromagnetic transition with molybdenum incorporation, accompanied by a shift in the magnetic easy-axis from parallel to perpendicular. Phase separation was found in the Fe(1-x)Cr(x)Cl(3) ternary alloy indicating that crystallographic structure compatibility plays an essential role in determining the miscibility of two parent compounds. Alloying across two similar (TMH) compounds appears to yield predictable results in properties as in the case of Co(1-x)Ni(x)Cl(2), while more exotic transitions, as in the case of Mo(1-x)Cr(x)Cl(3), can emerge by alloying dissimilar compounds. When dissimilarity reaches a certain limit, as with Fe(1-x)Cr(x)Cl(3), phase separation becomes more favorable. Future studies focusing on magnetic and structural phase transitions will reveal more insight into the effect of alloying in these TMH systems. / Dissertation/Thesis / Masters Thesis Materials Science and Engineering 2020 Materials Science 2D Magnets 2D Materials Alloying Chemical Vapor Transport Material Synthesis Transition Metal Halides

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