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Preparation of Discotic Liquid Crystals with Application to Organic Thin-Film TransistorSu, Jin-Fong 30 July 2008 (has links)
The thesis is divided into two parts. One is about the preparation of discotic liquid crystals Acid-6. The other is about the growth of Acid-6 thin film by thermal evaporation on silicon oxide surfaces and modified silicon oxide surfaces such as self-assembled monolayer(SAM) in different temperature. The surface morphology and molecular orientation of the thin film were studied by Atomic Force Microscopy(AFM) , X-ray Diffraction (XRD) , and then they were applicated to organic thin film transistor and measured properties by Semiconductor Parameter Analyzer.
In the second part of our research, our expectative characteristics was not observed in different temperature and substructure. In the other side, we guessed that because discotic liquid crystals Acid-6 is negative semiconductor materials, so it is susceptible to hydrosphere, thus we can¡¦t observe the electric characteristic of OTFT in the atmosphere. In addition, due to discotic liquid crystals Acid-6 have biggish moleculer weight, thus its viscosity was so big that cause the diameter of Acid-6 crystals to be too small. Therefore, it influenced the carrier mobility. Finally, from the aspect of procedure about fabrication of the devices we can discuss whether this parameter of this device can apply to OTFT.
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Guiding ambiphilic molecular alignment using patterned polydimethylsiloxane surfacesHsieh, Chiung-wen 27 July 2009 (has links)
Controlling the orientation of liquid crystal molecules in LC displays is extremely important for optimizing device performance. The method most commonly used in industry today involves rubbing the surface of the polymer-coated glass substrates used in the displays with a velvet cloth to create microscopic grooves. Berreman theory states that the liquid crystal molecules then align along the direction of the grooves. Alternatively, some literature shows that the friction caused by rubbing aligns the polymer chains in the surface layer which then attract and align the liquid crystal molecules along the direction of the chains. Even now, it is still unclear exactly how the process of rubbing the surface causes the liquid crystal molecules to align in an orderly manner.
This thesis describes a systematic study of the physical and chemical influence of the substrate on the alignment and orientation of liquid crystal molecules. We used Fourier Transform Infrared spectroscopy (FTIR) to identify surface chemistry, contact angle measurements to determine the surface energy, and atomic force microscopy (AFM) to observe the alignment of liquid crystal on the surfaces. In the course of this study, we have gained insight into how the physical and chemical properties of the surface affect the molecular arrangement in the solid-liquid interface. Our results can be applied not only to LCD technology, but more generally to biochips and biosensor devices.
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Utilizing AFM for Surface Force Measurement and Structure CharacterizationChao, Wei-chieh 27 July 2009 (has links)
Atomic force microscopy (AFM) is an important technology that allows researchers to probe local surface properties at nanometer length scales. In addition to surface topography, the AFM can probe many types of tip-surface interactions (including adhesion and friction) to gain a better understanding of the chemical properties of surfaces. This thesis contains two experiments which utilize AFM to in addition to several other techniques to study (1) Self Assembled Monolayer (SAM) formation and corrosion and (2) intermolecular and surface/molecular effects on gramicidin film formation and molecular orientation.
In the first experiment, N-octadecyltrichlorosilane (OTS) molecules were self-assembled onto silicon samples. We observed that OTS required a very short time (about 15 seconds) to complete the formation of the monolayer on surface. However, this SAM film was highly susceptible to corrosion by the strong oxidant (KMnO4), resulting in a chemical change to the film from hydrophobic functional groups (CH3) to hydrophilic functional groups (OH). In subsequent experiments, we observed that if the SAMs were formed using longer exposure times (about 24 hours), they were highly resistant to corrosion. Fourier Transform Infrared Spectroscopy (FTIR) and X-Ray Photoelectron Spectroscopy (XPS) also showed that the 24 hour growth SAM films were densely packed. These results indicate that SAM films based on organosilane molecules can protect the surface from corrosion, and further that more densely packed SAMs exhibit better anti-corrosion performance than less dense films.
In the second experiment, the antibacterial peptide Gramicidin was used to study how intermolecular and surface energy properties can influence the aggregation and film formation of molecules on several surfaces. Gramicidin has a unique physical and chemical structure with hydrophobic side chain and hydrophilic ends. Here, we have used three different substrates (Silicon, Mica, and Graphite) to study intermolecular interactions, aggregation, and orientation of Gramicidin peptide. Langmuir-Blodgett methods were also used to study aggregation and molecular orientation at the solid-liquid interface.
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Study on molecular packing and its effect on the tribological properties of ultrathin molecular filmsCheng, Yue-an 27 July 2009 (has links)
Self assembled monolayer films (SAMs) deposited on silicon surfaces have gained considerable interest due to their ability to modify surface properties for advanced applications in sensors, MEMS, and NEMS devices. These molecular films are typically deposited on silicon surfaces from solution using a variety of solvents, which can influence the molecular packing and quality of the films. To better understand these effects, we have performed a systematic solvent effect study of the growth of n-Octadecyltrichlorosilane (OTS) on silicon substrates using chloroform, dichloromethane, toluene, benzene and hexadecane. The films were characterized using contact angle measurements, Fourier Transform Infrared Spectroscopy (FTIR), and Atomic Force Microscopy (AFM) to evaluate the SAM growth rate and film quality. Lateral Force Microscopy (LFM) and transmission FTIR were used to characterize the molecular packing. Finally, we used AFM to make adhesion measurements on the films and correlated these results with friction data. These techniques provide a means to characterize the local nanoscale packing of the films. The Hertzian contact model was used to model and describe the adhesion and friction result. Our results show that using hexadecane as the solvent produced OTS films with the highest density molecular packing. By comparing to Langmuir-Blodgett SAM film deposition methods, we show that it is the intermolecular interaction between the solvent molecules and OTS that determines this density. Thus, the structure and chemical properties of the solvent molecule strongly influences the molecular packing, quality, and performance of the SAM film.
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Molecular level interactions of large area 2D materialsNa, Seung Ryul 10 August 2015 (has links)
Two-dimensional materials such as self-assembled monolayers (SAMs), graphene, etc. are candidate materials for improving the performance of microelectronics components and MEMS/NEMS devices. In view of their relatively large in-plane dimensions, surface forces are likely to dominate their behavior. The purpose of the current work was to extract not only the adhesion energy (or steady state fracture toughness) but also the traction-separation relation associated with interactions between various two-dimensional materials and substrates. In particular, interactions between SAMs terminated by carboxyl and diamine (COOH/NMe2) groups, hydroxylated silicon surfaces, graphene and silicon, graphene and its seed copper and graphene and epoxy over large areas was considered. Traction-separation relations, which are a continuum description of such molecular interactions, were determined by a direct method, which makes use of measurements of crack tip opening displacements; an inverse approach where the key parameters are extracted by comparing measured global parameters with finite element solutions and a hybrid approach in which the direct method was supplemented by finite element analysis. Furthermore, the surface free energy of graphene was measured by contact angle measurements.
The most striking observation across all the interactions that were considered is that the interaction ranges were much larger than those attributed to van der Waals forces. While van der Waals models might have been at play between graphene and its seed copper foil and graphene and epoxy, the adhesion energies were surprisingly high. This coupled with the long interaction range suggests that roughness effects modulated the basic force field. Interactions between graphene and silicon and hydroxylated silicon surfaces may have been due to capillary and/or electrostatic again possibly modulated by roughness. The interactions between COOH and NMe2 SAMs became stronger under vacuum, which may have induced chemical bonding, and tougher under mixed-mode loading. / text
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Electronic Structure Predictions for Properties of Organic MaterialsVogt, Leslie January 2011 (has links)
Electronic structure calculations of organic molecules are an important set of tools to gain understanding of molecular structures. This thesis presents two separate contributions to applying quantum chemistry to organic molecules. In the first section, the computational cost of a post-Hartree-Fock method is improved for large molecules by using graphical processing units. In this work, the resolution-of-the-identity second-order Møller-Plesset perturbation theory (RI-MP2) algorithm was adapted to send the large matrix multiplication steps to be run on a graphics co-processor. As a result, the calculations were performed up to 15x faster than a standard implementation for large molecules such as taxol. In the second section of the thesis, density functional theory is used to predict the molecular dipole moments of molecules that form self-assembled monolayers (SAMs) on metal surfaces. The dipole moment of the molecule that is aligned perpendicular to the surface in a SAM changes the work function of the surface. The calculated dipole moments correlate with the current density measured for the junctions by experimental collaborators. This result holds for a series of alkane chains with even and odd numbers of carbons and for molecules that have an amide group substituted for an ethylene unit. / Chemistry and Chemical Biology
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Passivation of III-V Semiconductor SurfacesContreras, Yissel, Muscat, Anthony 08 November 2013 (has links)
Computer processor chips of the last generation are based on silicon, modified to achieve maximum charge mobility to enable fast switching speeds at low power. III-V semiconductors have charge mobilities that are much higher than that of silicon making them suitable candidates for boosting the performance of new electronic devices. However, III-V semiconductors oxidize rapidly in air after oxide etching and the poor quality of the resulting oxide limits device performance. Our goal is to design a liquid-phase process flow to etch the oxide and passivate the surface of III-V semiconductors and to understand the mechanism of layer formation.Self-assembled monolayers of 1-eicosanethiol (ET) dissolved in ethanol, IPA, chloroform, and toluene were deposited on clean InSb(100) surfaces. The InSb passivated surfaces were characterized after 0 to 60 min of exposure to air. Ellipsometry measurements showed a starting overlayer thickness (due to ET, oxides, or both) of about 20 Å in chloroform and from 32 to 35 Å in alcohols and toluene. Surface composition analysis of InSb with X-ray photoelectron spectroscopy after passivation with 0.1 mM ET in ethanol confirmed the presence of ET and showed that oxygen in the Auger region is below detection limits up to 3 min after the passivation. Our results show that a thiol layer on top of a non-oxidized or low-oxide semiconductor surface slows oxygen diffusion in comparison to a surface with no thiol present, making this a promising passivation method of III-V semiconductors.
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Organic Sulfenyl Chlorides as Precursors for the Modification of Gold SurfacesMuhammad, Hamida 16 May 2013 (has links)
Self-assembled monolayers (SAMs) of organosulfur precursors on gold have been extensively used since they offer a wide range of technological applications such as corrosion inhibition, lubrication, adhesion promotion/inhibition, nanofabrication, chemical and biosensors, catalysis, and molecular electronics. Furthermore, the electronic and optical properties of aromatic SAMs make them a potential candidate for molecular electronics. However, these practical applications are limited by the short-range ordering, low packing density, irreproducibility, and inferior quality of SAMs, which are more critical for aromatic SAMs. Therefore, the discovery of alternative precursors is essential.
This thesis reports for the first time, the use of organic sulfenyl chlorides as precursors for the modification of gold surfaces. These precursors may help to overcome some practical limitations of the traditional organosulfur precursors. The modification is done in a non-aqueous medium. Characterization of the modified surfaces is performed by X-ray photoelectron spectroscopy (XPS), cyclic voltammetry (CV), polarization modulation infrared reflection absorption spectroscopy (PM-IRRAS), and scanning tunnelling microscopy (STM).
Through the use of 4-nitrophenyl sulfenyl chloride, evidence for the formation of well-ordered aromatic SAMs formation on gold is provided. XPS data shows that the modification involves the scission of the S-Cl bond. PM-IRRAS studies further indicate that the adsorbed molecules are nearly vertically oriented on the surface. Both short and long-range well-ordered aromatic SAMs (a 4 x √3 rectangular and √3 x √3 hexagonal unit cells) are obtained from the STM images using two different modification conditions. This molecular density is usually only observed for aliphatic SAMs using the traditional precursors. Along with the main hexagonal lattice, the reversible distinct superstructures including hexagons, partial hexagons, parallelograms, and zigzags resulting from specific arrangements of adsorbed molecules provide submolecular details. This is the first direct experimental example, where the STM has shown its effectiveness to provide physical structure information of standing-up aromatic SAMs at room temperature. This work also provides some insight into a heavily debated issue regarding the origin of the various features and contrasts obtained in STM images of SAMs.
The use of 2-nitrophenyl sulfenyl chloride and 2,4-dinitrophenyl sulfenyl chloride for the formation of aromatic SAMs on Au provides some insight regarding the modification extent and the effect of a nitro substituent (at ortho position ) on the quality of nitrophenyl thiolate SAMs on gold. XPS, PM-IRRAS, electrochemistry and STM provide evidence for the formation of less ordered, low density and less stable SAMs that may decompose to sulfur at longer modification times.
The efficient deposition of sulfur on gold is observed using a series of substituted methane sulfenyl chlorides (triphenylmethane sulfenyl chloride, trichloromethane sulfenyl chloride and chlorocarbonyl sulfenyl chloride). The XPS, STM and electrochemical data show the formation of high density sulfur phases. These include rhombus, rectangular, and zig-zag sulfur structures. A mechanism is suggested involving the cleavage of the S-Cl bond and the ejection of the molecular backbone. This study also suggests that substituted methane sulfenyl chlorides do not form long-range ordered SAMs.
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Two-dimensional arrangement of fine silica spheres on self-assembled monolayersMasuda, Yoshitake, Seo, Won-Seon, Koumoto, Kunihito, 増田, 佳丈, 河本, 邦仁 01 February 2001 (has links)
No description available.
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Self-assembled monolayers as platform for biosensorsWang, Qin, Shannon, Curtis. January 2005 (has links) (PDF)
Thesis(M.S.)--Auburn University, 2005. / Abstract. Vita. Includes bibliographic references.
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