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Author: Shashi Krishna Murthy Publisher: ISBN: Category : Languages : en Pages : 122
Book Description
Neural prostheses are micron-scale integrated circuit devices that are under development for the treatment of brain and spinal cord injuries. A key challenge in the fabrication of these silicon- based devices is the protection of the electronic components from the ambient body environment. There is a need for a biopassivation coating on these devices that is chemically inert and electrically insulating with good adhesion to the underlying silicon substrate. Fluorocarbon-organosilicon copolymers are of interest for this application because they have the desirable attributes of both fluorocarbon and organosilicon polymers, such as low dielectric constant, thermal stability, and good adhesion to silicon. Chemical vapor deposition (CVD) is an attractive synthetic technique for this application because it is single-step, requires no solvent, and allows conformal coatings to be deposited on substrates with complex topographies and small dimensions. Fluorocarbon-organosilicon copolymers have been synthesized by hot-filament CVD, a thermal CVD technique. Control over deposition rate and chemical structure is achieved by precursor choice and variation of filament temperature. Chemical characterization by infrared (FTIR), x-ray photoelectron (XPS), and solid-state nuclear magnetic resonance (NMR) spectroscopies indicates that the copolymer films range from highly cross-linked films to flexible films comprised mostly of linear polymer chains. This variation in chemical composition influences physical properties such as thermal stability and flexibility. The possibility of creating bioactive surface coatings has been explored by using the techniques of CVD and solution chemistry in combination. Chains of poly(acrylamide) have been grafted onto fluorocarbon-organosilicon films as a first step towards the design of bioactive coatings that could potentially enhance the performance of medical implants.
Author: Shashi Krishna Murthy Publisher: ISBN: Category : Languages : en Pages : 122
Book Description
Neural prostheses are micron-scale integrated circuit devices that are under development for the treatment of brain and spinal cord injuries. A key challenge in the fabrication of these silicon- based devices is the protection of the electronic components from the ambient body environment. There is a need for a biopassivation coating on these devices that is chemically inert and electrically insulating with good adhesion to the underlying silicon substrate. Fluorocarbon-organosilicon copolymers are of interest for this application because they have the desirable attributes of both fluorocarbon and organosilicon polymers, such as low dielectric constant, thermal stability, and good adhesion to silicon. Chemical vapor deposition (CVD) is an attractive synthetic technique for this application because it is single-step, requires no solvent, and allows conformal coatings to be deposited on substrates with complex topographies and small dimensions. Fluorocarbon-organosilicon copolymers have been synthesized by hot-filament CVD, a thermal CVD technique. Control over deposition rate and chemical structure is achieved by precursor choice and variation of filament temperature. Chemical characterization by infrared (FTIR), x-ray photoelectron (XPS), and solid-state nuclear magnetic resonance (NMR) spectroscopies indicates that the copolymer films range from highly cross-linked films to flexible films comprised mostly of linear polymer chains. This variation in chemical composition influences physical properties such as thermal stability and flexibility. The possibility of creating bioactive surface coatings has been explored by using the techniques of CVD and solution chemistry in combination. Chains of poly(acrylamide) have been grafted onto fluorocarbon-organosilicon films as a first step towards the design of bioactive coatings that could potentially enhance the performance of medical implants.
Author: Thomas Bryan Casserly Publisher: ISBN: Category : Languages : en Pages : 326
Book Description
Chemical vapor deposition (CVD) produced films for a wide array of applications from a variety of organosilicon and organic precursors. The structure and properties of thin films were controlled by varying processing conditions such as the method and power of precursor activation, pressure, flow rates, and substrate temperature. Systematic variance of deposition conditions allows for the design of materials for a specific application, highlighting the versatility of CVD processes. Spectroscopic tools including Fourier transform infrared spectroscopy, variable angle spectroscopic ellipsometry, X-ray photoelectron spectroscopy, Raman spectroscopy, and nuclear magnetic resonance (NMR) spectroscopy were utilized to characterize film structure and understand the relationship between the structure and properties of materials. Computational quantum mechanics is a power tool applied to explain observed phenomena such as unreferenced chemical shifts in the 29Si NMR of organosilicon thin films, and to examine the thermochemistry of a family of methyl- and methoxymethylsilanes enabling the prediction of initial reactions occurring in the CVD process.
Author: Jeffrey B. Fortin Publisher: Springer Science & Business Media ISBN: 147573901X Category : Science Languages : en Pages : 112
Book Description
Chemical Vapor Deposition Polymerization - The Growth and Properties of Parylene Thin Films is intended to be valuable to both users and researchers of parylene thin films. It should be particularly useful for those setting up and characterizing their first research deposition system. It provides a good picture of the deposition process and equipment, as well as information on system-to-system variations that is important to consider when designing a deposition system or making modifications to an existing one. Also included are methods to characterizae a deposition system's pumping properties as well as monitor the deposition process via mass spectrometry. There are many references that will lead the reader to further information on the topic being discussed. This text should serve as a useful reference source and handbook for scientists and engineers interested in depositing high quality parylene thin films.
Author: Nathan Jeffrey Trujillo Publisher: ISBN: Category : Languages : en Pages : 216
Book Description
The new millennium has brought fourth many technological innovations made possible by the advancement of high speed integrated circuits. The materials and energy requirements for a microchip is orders of magnitude higher than that of "traditional" goods, and current materials management requirements for EHS friendly low-k processing require a 10% annual increase in raw materials utilization. Initiated Chemical Vapor Deposition (iCVD) is a low-energy, one step, solvent-free process for producing polymeric thin films This thesis describes the deposition of a novel low-k iCVD precursor, 1,3,5,7-tetravinyltetramethylcylcotetrasiloxane (V4D4). The high degree of organic content in the as-deposited film affords the ability to tune the film's properties by annealing. The incorporation of atmospheric oxygen at high temperatures enhances the mechanical and electrical properties of the films. Films annealed at 410'C have a dielectric constant of 2.15, hardness and modulus of 0.78 GPa and 5.4 GPa, respectively. These values are comparatively better than previously reported results for CVD low-k films. Environmentally friendly low-k processing encompasses materials and energy management in the entire integration process, including lithography. Colloidal lithography was combined with iCVD and capillary force lithography to create spatially addressable grafted polymer pattern nanostructures, without the need for expensive lithography tools. Using this method, we pattern our novel low dielectric constant polymer down to 25 nm without the need for environmentally harmful solvents. Furthermore, these grafted patterns were produced for a broad material set of functional organic, fluorinated, and silicon containing polymers. A variation of this process created amine functionalized biocompatible conducting polymer nanostructure patterns for biosensor applications. These were fabricated using grafting reactions between oxidative chemical vapor deposition (oCVD) PEDOT conducting polymers and amine functionalized polystyrene (PS) colloidal templates. Carboxylate containing oCVD copolymer patterns were used to immobilized fluorescent dyes. Fluorescent colloidal particles were assembled within dyed PEDOT-co-TAA copolymer nanobowl templates to create bifunctional patterns for optical data storage applications. Finally, UV and e-beam lithography were used to pattern covalently tethered vinyl monolayers for resist-free patterning of iCVD and oCVD polymers, using environmentally innocuous solvents.
Author: Christy Danielle Petruczok Publisher: ISBN: Category : Languages : en Pages : 178
Book Description
Initiated Chemical Vapor Deposition (iCVD) is a versatile, one-step process for synthesizing conformal and functional polymer thin films on a variety of substrates. This thesis emphasizes the development of tools to further enable the use of iCVD for industrial applications. The ability to pattern polymer thin films is a prerequisite for device fabrication. Two methods were developed for patterning iCVD polymers. The first technique facilitated patterning of nano- and microscale features of any iCVD thin film on planar surfaces. Retention of polymer functionality was demonstrated by incorporating the features into high-resolution resistive sensors. The second method adapted photolithographic techniques to achieve patterning on highly curved surfaces. Non-planar substrates were coated with a uniform layer of a functionalized, photoreactive iCVD polymer and exposed to ultraviolet light through a flexible mask. Exposed regions became insoluble in a developing solvent. The resolution and sensitivity of this iCVD-based negative photoresist were comparable to those of commercial products. Additionally, the patterned polymer was used as a mask for patterning metal on planar and curved surfaces. iCVD is typically a semi-continuous process. A batch process was investigated in order to minimize the use of expensive and corrosive reactants. The chemical functionality and conformality of the films were unaffected by the change in processing mode. Reaction yield was improved by one to two orders of magnitude for several film chemistries. iCVD is also unique in that it enables the deposition of cross-linked polymer films, which are difficult to create using conventional, solution-based methods. To potentially enhance durability, cross-linked poly(divinylbenzene) and poly(4-vinylpyridine-co-divinylbenzene) films were synthesized via iCVD. This is the first vapor-phase synthesis of the copolymer, which is a major component of many commercial ion exchange membranes. The degree of cross-linking was quantified using spectroscopic methods and was tightly controlled by adjusting the flow rate of divinylbenzene. Corresponding changes in the elastic moduli of the films were confirmed using nanoindentation. The first vapor-phase synthesis of poly(vinyl cinnamate) was also demonstrated. The cross-linking density of this polymer increases upon exposure to ultraviolet light and is readily quantifiable. Vinyl cinnamate was incorporated into a copolymer with N-isopropylacrylamide, yielding a temperature and light-responsive thin film.
Author: Daniel D. Burkey Publisher: ISBN: Category : Languages : en Pages : 284
Book Description
Organosilicon matrix material resulted in film collapse rather than the formation of voids. In order to prevent this, an extensive study of the mechanical properties of the matrix material was performed, with identification of key structure-property-processing relationships that allowed for the enhancement of mechanical properties while maintaining favorable conditions for the deposition of the porogen species. Integration of the optimized system and subsequent removal of the porogen sacrificial material resulted in thin films with properties suggesting porosity and dielectric constants as low as 2.3.
Author: Omar Bchir Publisher: ISBN: 9780530008301 Category : Technology & Engineering Languages : en Pages : 432
Book Description
Abstract: PhD Dissertation: MOCVD of WNx Dissertation Discovery Company and University of Florida are dedicated to making scholarly works more discoverable and accessible throughout the world. This dissertation, "Chemical Vapor Deposition of Thin Films for Diffusion Barrier Applications" by Omar James Bchir, was obtained from University of Florida and is being sold with permission from the author. A digital copy of this work may also be found in the university's institutional repository, IR@UF. The content of this dissertation has not been altered in any way. We have altered the formatting in order to facilitate the ease of printing and reading of the dissertation.
Author: Shashi Krishna Murthy
Author: Shashi Krishna Murthy
Author: Shashi K. Murthy
Author: Thomas Bryan Casserly
Author: Jeffrey B. Fortin
Author: Nathan Jeffrey Trujillo
Author: 
Author: Christy Danielle Petruczok
Author: Daniel D. Burkey
Author: Stefan Schröder
Author: Omar Bchir