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Surface and Interfacial Studies of Metal-Organic Chemical Vapor Deposition of CopperNuesca, Guillermo M. 12 1900 (has links)
The nucleation and successful growth of copper (Cu) thin films on diffusion barrier/adhesion promoter substrates during metal-organic chemical vapor deposition (MOCVD) are strongly dependent on the initial Cu precursor-substrate chemistry and surface conditions such as organic contamination and oxidation. This research focuses on the interactions of bis(1,1,1,5,5,5-hexafluoroacetylacetonato)copper(II), [Cu(hfac)2], with polycrystalline tantalum (Ta) and polycrystalline as well as epitaxial titanium nitride (TiN) substrates during Cu MOCVD, under ultra-high vacuum (UHV) conditions and low substrate temperatures (T < 500 K). The results obtained from X-ray photoelectron
spectroscopy (XPS), Auger Electron Spectroscopy (AES) and Temperature Programmed Desorption (TPD) measurements indicate substantial differences in the chemical reaction pathways of metallic Cu formation from Cu(hfac)2 on TiN versus Ta surfaces.
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Process optimization and electrical characterization of ZnS:Mn electroluminescent phosphors deposited by halide transport chemical vapor depositionHusurianto, Sjamsie 18 June 1998 (has links)
Process development of halide transport chemical vapor deposited (HTCVD)
ZnS:Mn thin film has been studied. To this end, electrical characterization of HTCVD
ZnS:Mn electroluminescent devices has been used. Process optimization focused on a
simple design of experiment (DOE) with brightness as the major response.
Deposition parameters such as HCl and H���S gas flow rates, ZnS and Mn source
temperatures and substrate temperature were studied. A substrate temperature of 550��C gives the brightest devices. ZnS source temperature and H���S gas flow rate are
insignificant parameters according to the statistical analysis. However HCl gas flow
rate and Mn source temperature show strong interaction. It is proposed that the
incorporation of Cl into the ZnS:Mn film causes the interaction. A Cl defect is also
consistent with anomalous electrical behavior observed in the devices. Cl defects are
thought to precipitate at the grain boundaries of the initial growth interface, then
diffuse (or migrate) along the grain boundaries and possibly into the bulk crystal. This
defect will easily form negative charge leading to asymmetric space charge in the bulk of the phosphor.
Since the defects are believed to originate from the nucleation of Cl at high grain boundary density, one potential solution is to remove the Cl source as the grains begin to grow and only later expose the film to Cl. While film growth without HCl present at the beginning of deposition leads to brighter films, it is a sub-optimal solution. Part of the ZnS host does not have luminescent centers. It is believed other processing solutions need to be realized to make the HTCVD system viable. / Graduation date: 1999
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A halide transport chemical vapor deposition reactor system for deposition of ZnS:Mn electroluminescent phosphorsMiller, R. Todd 07 April 1995 (has links)
Graduation date: 1995
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Analysis of Thin Films Growth in Vertical CVD ReactorCheng, Wei-Ming 24 June 2002 (has links)
Abstract
The development and advancement of microelectronics technology has been very dramatic. However the cost of creating new process technology by using experiment has been very high. By using computer simulation to evaluate the performance of these equipment, we are able to achieve the same goal at a much lower cost.
The reactor of chemical vapor deposition (CVD) is very important to semiconductor production process. This research use numerical method (simulation) to study the process parameters of Low-Pressure Chemical Vapor Deposition (LPCVD) of silicon (Si). In this simulation, the CVD reactor modelings are constructed and discredited by using implicit finite volume method. The grids are arranged in a staggered manner for the discretization of the governing equations. Then the SIMPLE-type algorithm is used to solve all of the discretized algebra equations.
Many people in the field are beginning to realize that these challenges can no longer be tackled with the traditional trial-and-error method which have dominated the CVD technology since its beginning, and that modeling may lead to better process and equipment design, reduced costs, and improved IC manufacturing. It is also to be expected that in the future, detailed CVD simulation models will not only be used in design and optimization, but also in real-time process control.
Key word: chemical vapor deposition, flow simulation, natural convection.
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Numerical study of combustion chemical vapor deposition processesAmaya, John 05 1900 (has links)
No description available.
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Chemical vapor deposition of titanium diboride and polycrystalline silicon for use in thin film solar cellsBeckloff, Bruce Nick 05 1900 (has links)
No description available.
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Chemical vapor deposition (CVD) of novel carbon solidsStratulat, Alisa M. January 2009 (has links)
Honors Project--Smith College, Northampton, Mass., 2009. / Includes bibliographical references (p. 91-95)
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Catalytic chemical vapor deposition synthesis of carbon nanotubes from methane on SiO supported Fe and Fe-Ni catalysts /Nakagawa, Ayako. January 1900 (has links)
Thesis (M.S.)--Oregon State University, 2009. / Printout. Includes bibliographical references (leaves 74-82). Also available on the World Wide Web.
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Synthesis of novel carbon materials and their applicationsKleckley, Stephen H. 01 January 1999 (has links)
No description available.
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Selectivity Failure in the Chemical Vapor Deposition of TungstenCheek, Roger W. (Roger Warren) 08 1900 (has links)
Tungsten metal is used as an electrical conductor in many modern microelectronic devices. One of the primary motivations for its use is that it can be deposited in thin films by chemical vapor deposition (CVD). CVD is a process whereby a thin film is deposited on a solid substrate by the reaction of a gas-phase molecular precursor. In the case of tungsten chemical vapor deposition (W-CVD) this precursor is commonly tungsten hexafluoride (WF6) which reacts with an appropriate reductant to yield metallic tungsten. A useful characteristic of the W-CVD chemical reactions is that while they proceed rapidly on silicon or metal substrates, they are inhibited on insulating substrates, such as silicon dioxide (Si02). This selectivity may be exploited in the manufacture of microelectronic devices, resulting in the formation of horizontal contacts and vertical vias by a self-aligning process. However, reaction parameters must be rigorously controlled, and even then tungsten nuclei may form on neighboring oxide surfaces after a short incubation time. Such nuclei can easily cause a short circuit or other defect and thereby render the device inoperable. If this loss of selectivity could be controlled in the practical applications of W-CVD, thereby allowing the incorporation of this technique into production, the cost of manufacturing microchips could be lowered. This research was designed to investigate the loss of selectivity for W-CVD in an attempt to understand the processes which lead to its occurrence. The effects of passivating the oxide surface with methanol against the formation of tungsten nuclei were studied. It was found that the methanol dissociates at oxide surface defect sites and blocks such sites from becoming tungsten nucleation sites. The effect of reactant partial pressure ratio on selectivity was also studied. It was found that as the reactant partial pressures are varied there are significant changes in the product partial pressure ratios, which are associated with gas phase reactions which contribute to the loss of selectivity.
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