Substrate and Catalyst Design for Chemical Vapor Deposition Synthesis of Carbon Nanotubes on Si, Cu and SiC PDF Download

Author: Ge Li
Publisher:
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Category :
Languages : en
Pages :

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This thesis discussed the design of substrate and catalyst for chemical vapor deposition synthesis of carbon nanotubes (CNT). It was focused on synthesis CNTs on the various substrates, such as Si, Cu and SiC. The research was structured as following: (1) characterization of the Al2O3 buffer layer produced by plasma oxidation in order to find out the its effect on CNT growth; (2) study of the position parameters in CVD system to optimize process condition for manufacturing CNTs; (3) exploring novel composite catalyst alloys; (4) design new substrate for synthesis of vertically aligned CNTs on Cu and SiC for thermal application. Advanced surface analysis techniques were used to explore the role of AI2O3 supporting layer and of the composite catalyst. Although the data is insufficient for coming to a conclusion on the mechanism behind CNT super-growth, the preliminary studies provide guidance for selecting catalyst composite which will allow scaling up CNT production. A series of experiments using two CVD system (ET 1000 & ET 3000) were conducted which allowed for optimize the growth parameter and produce CNT arrays with uniform length. Vertically aligned CNTs arrays were successfully synthesized on copper and SiC substrates by adding supporting layers and adjusting the CVD growth conditions. This achievement engenders a wide range of future application in the field of thermal management.

Author: Haider H. Almkhelfe
Publisher:
ISBN:
Category :
Languages : en
Pages :

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The continued depletion of fossil fuels and concomitant increase in greenhouse gases have encouraged worldwide research on alternative processes to produce clean fuel. Fischer-Tropsch synthesis (FTS) is a heterogeneous catalytic reaction that converts syngas (CO and H2) to liquid hydrocarbons. FTS is a well-established route for producing clean liquid fuels. However, the broad product distribution and limited catalytic activity are restricting the development of FTS. The strong interactions between the active metal catalyst (Fe or Co) and support (Al2O3, SiO2 and TiO2) during post-synthesis treatments of the catalyst (such as calcination at ~500°C and reduction ~550°C) lead to formation of inactive and unreducible inert material like Fe2SiO4, CoAl2O4, Co2SiO4. The activity of FTS catalyst is negatively impacted by the presence of these inactive compounds. In our study, we demonstrate the use of a modified photo-Fenton process for the preparation of carbon nanotube (CNT)-supported Co and Fe catalysts that are characterized by small and well-dispersed catalyst particles on CNTs that require no further treatments. The process is facile, highly scalable, and involves the use of green catalyst precursors and an oxidant. The reaction kinetic results show high CO conversion (85%), selectivity for liquid hydrocarbons and stability. Further, a gaseous product mixture from FTS (C1-C4) was utilized as an efficient feedstock for the growth of high-quality, well-aligned single-wall carbon nanotube (SWCNT) carpets of millimeter-scale heights on Fe and (sub) millimeter-scale heights on Co catalysts via chemical vapor deposition (CVD). Although SWCNT carpets were grown over a wide temperature range (between 650 and 850°C), growth conducted at optimal temperatures for Co (850°C) and Fe (750°C) yielded predominantly SWCNTs that are straight, clean, and with sidewalls that are largely free of amorphous carbon. Also, low-temperature CVD growth of CNT carpets from Fe and Fe-Cu catalysts using a gaseous product mixture from FTS as a superior carbon feedstock is demonstrated. The efficiency of the growth process is evidenced by the highly dense, vertically aligned CNT structures from both Fe and Fe-Cu catalysts even at temperatures as low as 400°C-a record low growth temperature for CNT carpets obtained via conventional thermal CVD. The use of FTS-GP facilitates low-temperature growth of CNT carpets on traditional (alumina film) and nontraditional substrates (aluminum foil) and has the potential of enhancing CNT quality, catalyst lifetime, and scalability. We demonstrate growth of SWCNT carpets with diameter distributions that are smaller than SWCNTs in conventional carpets using a CVD process that utilizes the product gaseous mixture from Fischer-Tropsch synthesis (FTS-GP). The high-resolution transmission electron microscopic (HR-TEM) and Raman spectroscopic results reveal that the use of a high melting point metal as a catalyst promoter in combination with either Co (1.5 nm ± 0.7) at 850oC or Fe (1.9 nm ± 0.8) at 750oC yields smaller-diameter SWCNT arrays with narrow diameter distributions. Scalable synthesis of carbon nanotubes (CNTs), carbon nanofibers (CNFs), and onion like carbon (OLC) in a batch reactor using supercritical fluids as a reaction media is demonstrated. The process utilizes toluene, ethanol, or butanol as a carbon precursor in combination with ferrocene that serves as a catalyst precursor and a secondary carbon source. The use of supercritical fluids for growth does not only provide a route for selective growth of a variety of carbon nanomaterials, but also provides a unique one-step approach that is free of aggressive acid treatment for synthesis of CNT-supported metallic nanoparticle composites for catalysis and energy storage applications.

Author: GuiPing Dai
Publisher:
ISBN:
Category : Technology & Engineering
Languages : en
Pages : 0

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As a new carbon material in the twenty-first century, carbon nanotubes (CNTs) have excellent optical, electrical, magnetic, thermal, chemical, and mechanical properties. There are many synthesis methods to produce CNTs. Compared with other methods, chemical vapor deposition (CVD) is the most effective method that has broad prospects for large-scale control of CNTs in recent years due to its simple equipment, simple operation, and lower cost. In order to gain a comprehensive understanding of the controlling parameters about the formation of CNTs, this chapter reviews the latest progress in the preparation of CNTs by CVD from three of the most important influencing factors: carbon sources, catalysts, and substrates. Among them, the catalyst is the most influential factor for the morphology, structure, and properties of CNTs. It should be pointed out that many growth factors can control the particle size distribution, composition, and structure of the catalysts, such as catalyst substrate, metal transition components added, calcination temperature, etc.

Author: Noorhana Yahya
Publisher: Springer Science & Business Media
ISBN: 3642146732
Category : Technology & Engineering
Languages : en
Pages : 413

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This volume covers all aspects of carbon and oxide based nanostructured materials. The topics include synthesis, characterization and application of carbon-based namely carbon nanotubes, carbon nanofibres, fullerenes, carbon filled composites etc. In addition, metal oxides namely, ZnO, TiO2, Fe2O3, ferrites, garnets etc., for various applications like sensors, solar cells, transformers, antennas, catalysts, batteries, lubricants, are presented. The book also includes the modeling of oxide and carbon based nanomaterials. The book covers the topics: Synthesis, characterization and application of carbon nanotubes, carbon nanofibres, fullerenes Synthesis, characterization and application of oxide based nanomaterials. Nanostructured magnetic and electric materials and their applications. Nanostructured materials for petro-chemical industry. Oxide and carbon based thin films for electronics and sustainable energy. Theory, calculations and modeling of nanostructured materials.

Author:
Publisher:
ISBN:
Category :
Languages : en
Pages : 399

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Carbon nanotubes (CNT) constitute a new class of materials discovered in 1991 by Sumio Iijima that present unusual mechanical, electrical and thermal properties. Chemical Vapor Deposition (CVD) is the most promising synthesis route for producing large quantities of carbon nanotubes at a low cost. The first part of this thesis focuses on surface synthesis of high purity aligned carbon nanotubes using the CVD technique. High purity single wall and multi wall carbon nanotubes were grown using different substrates and catalysts. The substrates include non porous silicon substrates, porous silicon substrates, stainless steel substrates, stainless steel wires, and silicon cantilevers. The catalysts include molybdenum supported cobalt and alumina supported iron liquid catalysts, and iron and molybdenum catalysts deposited using e-beam evaporation and photolithographic techniques. Vertically aligned single wall and multi wall carbon nanotube forests were grown using the Easy Tube nanofurnace based on the CVD mechanism. The maximum length of the nanotubes grown was almost one millimeter and the diameters ranged from 1 to 100 nanometers. The nanotubes have a large surface area to volume ratio and a high electrochemical sensitivity. These properties may be useful for many applications such as reinforcing polymer composites, drug delivery, biomedical implants, neural imaging, development of biosensors for cancer detection, and other medical applications such as sensing and treating disorders like Epilepsy, Parkinson's disease, and Alzheimer's disease. Since nanotubes are proposed to be used for many biomedical applications, it becomes very important to understand the hazards of nanotubes and nanotechnology. Hence this thesis also presents a short overview of the toxicity of nanotubes. Carbon nanotube and nanofiber reinforced polymer composites have received tremendous amount of attention due to their interesting mechanical, electrical and thermal properties and potential applications. These composites potentially offer high stiffness, high strength, low electrical resistivity, dimensional stability, and light weight. Harnessing the unique physical properties of carbon nanostructures in materials applications has yet to be fully realized. The second part of this thesis mainly deals with improving the properties of composites using carbon nanofibers as fillers in an epoxy matrix. The single most important factor influencing use of carbon nanofibers as reinforcing fibers in polymer composites is their ability to effectively transfer the applied load in the matrix. The effective utilization of nanofibers in composites for structural applications depends strongly on the ability to disperse the nanofibers homogeneously in the matrix without damaging them. To be successfully used for enhancing the properties of composites, good interfacial bonding is required to achieve load transfer across the nanofiber-polymer interface. Hence, two main problems which arise in improving the properties are poor dispersion of the fibers in the composite and weak bonding between fibers and the matrix. These problems are attacked in this thesis by mechanical and chemical means. Solvent free functionalization, controlled sonication, high speed shear mixing at elevated temperatures, and high pressure casting are used to exfoliate the nanofibers in the epoxy. Pyrograf and CleanTech carbon nanofibers, which are similar to large diameter multi-wall carbon nanotubes, were used as filler materials in processing of composites. Incorporating 5 percentage by weight Pyrograf carbon nanofibers resulted in improvement of stiffness of the composite by about 45 percentage by weight and incorporating 5 percentage by weight CleanTech carbon nanofibers resulted in improvement of stiffness of the composite by 20 percentage by weight when compared to plain epoxy with out any nanofibers.

Author: Alexander Khovavko
Publisher: Springer Nature
ISBN: 3031641213
Category :
Languages : en
Pages : 163

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Author: Dane Tipton Christensen
Publisher:
ISBN:
Category :
Languages : en
Pages : 394

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Author: Yiming Li
Publisher:
ISBN:
Category :
Languages : en
Pages : 308

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Author: Ayako Nakagawa
Publisher:
ISBN:
Category : Chemical vapor deposition
Languages : en
Pages : 184

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Influences of operating conditions on the production of carbon nanotubes (CNTs) were studied using Fe and Fe-Ni bimetallic catalysts supported on silicon monoxide (SiO). The catalysts were prepared in three steps: (1) impregnation of SiO powders with ferric nitride or combinations of ferric and nickel nitrides, (2) oxidation of nitrides in an air stream, and (3) grinding the powders obtained. CNTs were successfully synthesized by catalytic CVD using NH3/CH4 mixtures in a horizontal tubular flow reactor. The following process parameters were varied to investigate their effects on the growth rates of CNTs. The morphologies of catalysts and product CNTs were observed by scanning electron microscope (SEM). The particle size of SiO, metal composition, metal loading, temperature for catalyst oxidation, extent of grinding of catalysts, NH3 pretreatment time, reaction temperature for CNT growth, reaction time, and NH3/CH4 feed ratio. Two different average sizes of SiO particles, 8 [mu]m and 44 [mu]m, were compared based on the growth of CNTs in 5 min. Catalysts supported on 44 [mu]m average sized SiO particles demonstrated higher yields when they were not pretreated in an NH3 stream. When 1 wt% Fe was loaded, aligned CNTs were formed, and a highest growth rate per unit mass of catalyst was observed. The range of oxidation temperature to achieve highest catalyst activities depended on metals and metal contents: 600 - 750°C for 1 wt% Fe, 450 - 600°C for 3 wt% Fe, and 750 - 900°C for Fe-Ni. Grinding catalysts for at least 3 minutes increased the growth rate of CNTs by approximately 40 percent. The growth of CNTs was enhanced when no NH3 pretreatment of catalysts was carried out, regardless of metals and metal contents. However, CNTs did not grow appreciably from methane without ammonia. An NH3/CH4 feed ratio of 0.15 - 0.25 was observed to yield highest growth rates. The reaction temperature to achieve highest CNT growth rates was found to be in the range between 990 and 1000 °C. The growth of CNTs was not linear but decreased with reaction time.

Author: Ryan Patrick Hines
Publisher:
ISBN:
Category :
Languages : en
Pages : 96

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Carbon nanotubes (CNTs) are solid carbon allotropes that feature high strength and high transport capabilities. When large populations of CNTs are synthesized simultaneously, they self-assemble into vertically oriented CNT forests (also called CNT arrays or CNT turfs). In the current work, three-dimensional CNT forest microstructures are engineered by selectively activating CNT growth on specific regions of a patterned substrate. The process is realized using a combination of two distinct chemical vapor deposition (CVD) processes in concert with silicon substrates independently patterned with regions of alumina, iron, or alumina and iron. The CVD process of both techniques require a catalyst nanoparticle to facilitate CNT growth and a hydrocarbon gaseous precursor. Floating catalyst CVD, a process in which CNT catalyst is delivered to a substrate in the vapor state, is compatible with oxide-coated substrates and not compatible with bare silicon surfaces. Fixed catalyst CVD utilizes a static iron film catalyst layer to support CNT synthesis. Regions of alumina support selective CNT forest growth with floating catalyst CVD, while regions of layered Al2O3/Fe support both fixed and floating catalyst growth when the fixed catalyst is activated first. By selectively and sequentially activating specific regions of a lithographically-defined substrate using the various CVD processes, complex 3D microstructures are demonstrated. The resultant CNT forest microstructures are characterized using scanning electron microscopy (SEM) and nanoindentation. Atomic force microscopy is used to analyze the behavior of the fixed iron catalyst during the high temperatures required for CVD processing.