Global ETD Search

11	Carbon Nanofiber-Polymer Composites for Electronic Applications Higgins, Bernadette Ann 17 May 2006 (has links) No description available. Chemistry, Polymer carbon nanofiber polymer styrene carbonate cyclic oligomers epoxy glycidol hyperbranched cationic polymerization electrical properties
12	Processing, Characterization And Performance Of Carbon Nanopaper Based Multifunctional Nanocomposites Liang, Fei 01 January 2012 (has links) Carbon nanofibers (CNFs) used as nano-scale reinforcement have been extensively studied since they are capable of improving the physical and mechanical properties of conventional fiber reinforced polymer composites. However, the properties of CNFs are far away from being fully utilized in the composites due to processing challenges including the dispersion of CNFs and the viscosity increase of polymer matrix. To overcome these issues, a unique approach was developed by making carbon nanopaper sheet through the filtration of well-dispersed carbon nanofibers under controlled processing conditions, and integrating carbon nanopaper sheets into composite laminates using autoclave process and resin transfer molding (RTM). This research aims to fundamentally study the processing-structure-property-performance relationship of carbon nanopaper-based nanocomposites multifunctional applications: a) Vibrational damping. Carbon nanofibers with extremely high aspect ratios and low density present an ideal candidate as vibrational damping material; specifically, the large specific area and aspect ratio of carbon nanofibers promote significant interfacial friction between carbon nanofiber and polymer matrix, causing higher energy dissipation in the matrix. Polymer composites with the reinforcement of carbon nanofibers in the form of a paper sheet have shown significant vibration damping improvement with a damping ratio increase of 300% in the nanocomposites. b) Wear resistance. In response to the iv observed increase in toughness of the nanocomposites, tribological properties of the nanocomposite coated with carbon nanofiber/ceramic particles hybrid paper have been studied. Due to high strength and toughness, carbon nanofibers can act as microcrack reducer; additionally, the composites coated with such hybrid nanopaper of carbon nanofiber and ceramic particles shown an improvement of reducing coefficient of friction (COF) and wear rate. c) High electrical conductivity. A highly conductive coating material was developed and applied on the surface of the composites for the electromagnetic interference shielding and lightning strike protection. To increase the conductivity of the carbon nanofiber paper, carbon nanofibers were modified with nickel nanostrands. d) Electrical actuation of SMP composites. Compared with other methods of SMP actuation, the use of electricity to induce the shape-memory effect of SMP is desirable due to the controllability and effectiveness. The electrical conductivity of carbon fiber reinforced SMP composites can be significantly improved by incorporating CNFs and CNF paper into them. A vision-based system was designed to control the deflection angle of SMP composites to desired values. The funding support from National Science Foundation and FAA Center of Excellence for Commercial Space Transportation (FAA COE CST) is acknowledged. Carbon nanofiber nanopaper multifunction mechanical property electrical property nanocomposites Engineering Materials Science and Engineering
13	Processing, Optimization And Characterization Of Fire Retardant Polymer Nanocomposites Zhuge, Jinfeng 01 January 2010 (has links) Fiber reinforced polymeric composites (FRPC) have superior physical and mechanical properties, such as high specific strength, light weight, and good fatigue and corrosion resistance. They have become competitive engineering materials to replace conventional metallic materials in many important sectors of industry such as aircraft, naval constructions, ships, buildings, transportation, electrical and electronics components, and offshore structures. However, since FRPC contain polymer matrix, the polymer composites and their structures are combustible. FRPC will degrade, decompose, and sometimes yield toxic gases at high temperature or subject to fire conditions. The objective of this study is to design and optimize fire retardant nanopaper by utilizing the synergistic effects of different nanoparticles. A paper-making technique that combined carbon nanofiber, nanoclay, polyhedral oligomeric silsesquioxanes, graphite nanoplatelet, and ammonium polyphosphate into self-standing nanopaper was developed. The fire retardant nanopaper was further incorporated into the polymer matrix, in conjunction with continuous fiber mats, through resin transfer molding process to improve fire retardant performance of structural composites. The morphology, thermal stability, and flammability of polymer composites coated with hybrid nanopaper were studied. The cone calorimeter test results indicated that the peak heat release rate of the composites coated with a CNF-clay nanopaper was reduced by 60.5%. The compact char material formed on the surface of the residues of the CNF-clay nanopaper was analyzed to understand the fire retardant mechanism of the nanopaper. The financial support from Office of Naval Research is acklowdged. nanocomposites hybrid nanopaper carbon nanofiber clay POSS xGnP flame resistance Engineering Mechanical Engineering
14	The Effect of Material and Processing on the Mechanical Response of Vapor-Grown Carbon Nanofiber/Vinyl Ester Composites Lee, Juhyeong 01 May 2010 (has links) The effects of material/fabrication parameters on vapor-grown carbon nanofiber (VGCNF) reinforced vinyl ester (VE) nanocomposite flexural moduli and strengths were investigated. Statistically reliable empirical response surface models were developed to quantify the effects of VGCNF type, use of dispersing agent, mixing method, and VGCNF loading on flexural properties. Optimal nanocomposite formulation and processing (0.74 phr oxidized VGCNFs, dispersing agent, and high-shear mixing) resulted in predicted flexural modulus and strength values 1.18 and 1.26 times those of the neat resin. Additional flexural, tensile, and compressive tests were performed for optimally configured nanocomposites cured in a nitrogen environment. While flexural and tensile moduli significantly increased with increasing VGCNF loading, the corresponding strengths fell below those of the neat resin. In contrast, nanocomposite ultimate compressive strengths significantly exceeded the neat resin strengths. Nanocomposites prepared using aggressive high-shear mixing displayed improved elastic moduli and substantially increased strengths relative to nanocomposites prepared using baseline methods. dispersion processing fabrication vapor-grown carbon nanofiber nanoreinforcement thermosets nanocomposites vinyl ester
15	Fabrication and Characterization of Plasmonic and Electrochemical Devices Towards Sensing Applications Robinson, Jendai E. 15 June 2017 (has links) No description available. Chemistry Carbon Nanofiber Chemical Sensing Biological Sensing Microscopy Electrochemistry Plasmonic Sensing
16	Development and Characterization of Functional Nanofiber Network (FNN) Materials Hakimelahi, Hamidreza (Nima) 19 September 2011 (has links) No description available. Chemical Engineering Chemistry Materials Science Nanotechnology Functional nanofiber network Ionic liquid Membranes Carbon nanofiber
17	Carbon Nanotube Smart Materials Kang, Inpil 23 May 2005 (has links) No description available. Engineering, Mechanical carbon nanotube carbon nanofiber strain sensor crack sensor corrosion sensor power transducer actuator
18	INFLUENCE OF NANOPARTICLES ON THE PHISICAL PROPERTIES OF FIBER REINFORCED POLYMER COMPOSITES Guerra, Dante Rene January 2009 (has links) No description available. Engineering Plastics Polymers Nanoparticles Carbon Nanofiber Multiwall Nanotube Mechanical Properties Composites Nanocomposites Polymer
19	Ultrasonically Aided Extrusion of Rubber Nanocomposites and Rubber Blends Choi, Jaesun 14 May 2013 (has links) No description available. Polymers ultrasound extrusion natural rubber NR styrene butadiene rubber SBR carbon black carbon nanotube carbon nanofiber dispersion properties morphology
20	A comparison of SPS and HP sintered, electroless copper plated carbon nanofibre composites for heat sink applications Ullbrand, Jennifer January 2009 (has links) <p>The aim of this study is to synthesize a material with high thermal conductivity and a low coefficient of thermal expansion (CTE), useful as a heat sink. Carbon nanofibres (CNF) are first coated with copper by an electroless plating technique and then sintered to a solid sample by either spark plasma sintering (SPS) or hot pressing (HP). The final product is a carbon nanofibre reinforced copper composite. Two different fibre structures are considered: platlet (PL) and herringbone (HB). The influence of the amount of CNF reinforcement (6-24 %wt), on the thermal conductivity and CTE is studied. CNF has an excellent thermal conductivity in the direction along the fibre while it is poor in the transverse direction. The CTE is close to zero in the temperature range of interest. The adhesion of Cu to the CNF surface is in general poor and thus improving the the wetting of the copper by surface modifications of the fibres are of interest such that thermal gaps in the microstructure can be avoided. The poor wetting results in CNF agglomerates, resulting in an inhomogeneous microstructure. In this report a combination of three different types of surface modifications has been tested: (1) electroless deposition of copper was used to improve Cu impregnation of CNF; (2) heat treatment of CNF to improve wetting; and (3) introduction of a Cr buffer layer to further enhance wetting. The obtained composite microstructures are characterized in terms of chemical composition, grain size and degree of agglomeration. In addition their densities are also reported. The thermal properties were evaluated in terms of thermal diffusivity, thermal conductivity and CTE. Cr/Cu coated platelet fibres (6wt% of CNF reinforcement) sintered by SPS is the sample with the highest thermal conductivity, ~200 W/Km. The thermal conductivity is found to decrease with increasing content of CNFs.</p> electroless plating SPS spark plasma sintering HP hot pressing CNF carbon nanofibre carbon nanofiber heat sinks thermal conductivity thermal diffusivity Cu composite flash technique Physics Fysik

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