Global ETD Search

251	Carbon Nanotube Based Systems for High Energy Efficient Applications Lahiri, Indranil 20 September 2011 (has links) In the current age of fast-depleting conventional energy sources, top priority is given to exploring non-conventional energy sources, designing highly efficient energy storage systems and converting existing machines/instruments/devices into energy-efficient ones. ‘Energy efficiency’ is one of the important challenges for today’s scientific and research community, worldwide. In line with this demand, the current research was focused on developing two highly energy-efficient devices – field emitters and Li-ion batteries, using beneficial properties of carbon nanotubes (CNT). Interface-engineered, directly grown CNTs were used as cathode in field emitters, while similar structure was applied as anode in Li-ion batteries. Interface engineering was found to offer minimum resistance to electron flow and strong bonding with the substrate. Both field emitters and Li-ion battery anodes were benefitted from these advantages, demonstrating high energy efficiency. Field emitter, developed during this research, could be characterized by low turn-on field, high emission current, very high field enhancement factor and extremely good stability during long-run. Further, application of 3-dimensional design to these field emitters resulted in achieving one of the highest emission current densities reported so far. The 3-D field emitter registered 27 times increase in current density, as compared to their 2-D counterparts. These achievements were further followed by adding new functionalities, transparency and flexibility, to field emitters, keeping in view of current demand for flexible displays. A CNT-graphene hybrid structure showed appreciable emission, along with very good transparency and flexibility. Li-ion battery anodes, prepared using the interface-engineered CNTs, have offered 140% increment in capacity, as compared to conventional graphite anodes. Further, it has shown very good rate capability and an exceptional ‘zero capacity degradation’ during long cycle operation. Enhanced safety and charge transfer mechanism of this novel anode structure could be explained from structural characterization. In an attempt to progress further, CNTs were coated with ultrathin alumina by atomic layer deposition technique. These alumina-coated CNT anodes offered much higher capacity and an exceptional rate capability, with very low capacity degradation in higher current densities. These highly energy efficient CNT based anodes are expected to enhance capacities of future Li-ion batteries. Carbon nanotube energy field emission lithium ion battery interface engineering emission characteristics electrochemical properties
252	Mechanical and Electrical Properties of Single-walled Carbon Nanotubes Synthesized by Chemical Vapor Deposition Yang, Yuehai 17 May 2013 (has links) Despite the tremendous application potentials of carbon nanotubes (CNTs) proposed by researchers in the last two decades, efficient experimental techniques and methods are still in need for controllable production of CNTs in large scale, and for conclusive characterizations of their properties in order to apply CNTs in high accuracy engineering. In this dissertation, horizontally well-aligned high quality single-walled carbon nanotubes (SWCNTs) have been successfully synthesized on St-cut quartz substrate by chemical vapor deposition (CVD). Effective radial moduli (Eradial) of these straight SWCNTs have been measured by using well-calibrated tapping mode and contact mode atomic force microscopy (AFM). It was found that the measured Eradial decreased from 57 to 9 GPa as the diameter of the SWCNTs increased from 0.92 to 1.91 nm. The experimental results were consistent with the recently reported theoretical simulation data. The method used in this mechanical property test can be easily applied to measure the mechanical properties of other low-dimension nanostructures, such as nanowires and nanodots. The characterized sample is also an ideal platform for electrochemical tests. The electrochemical activities of redox probes Fe(CN)63-/4-, Ru(NH3)63+, Ru(bpy)32+ and protein cytochrome c have been studied on these pristine thin films by using aligned SWCNTs as working electrodes. A simple and high performance electrochemical sensor was fabricated. Flow sensing capability of the device has been tested for detecting neurotransmitter dopamine at physiological conditions with the presence of Bovine serum albumin. Good sensitivity, fast response, high stability and anti-fouling capability were observed. Therefore, the fabricated sensor showed great potential for sensing applications in complicated solution. Carbon Nanotube Chemical Vapor Deposition Radial Modulus Biosensing Condensed Matter Physics
253	Obtenção e caracterização de mantas formadas por poli(fluoreto de vinilideno) obtidas por eletrofiação sob tratamento com plasma e dispersão de nanotubos de carbono / Fabrication and characterization of poly(vinylidene fluoride) mats obtained by electrospinning and plasma and carbon nanotubes dispersion treatments Nascimento, Ana Flávia, 1985- 02 September 2015 (has links) Orientador: Marcos Akira D'Ávila / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-26T18:13:53Z (GMT). No. of bitstreams: 1 Nascimento_AnaFlavia_M.pdf: 2761959 bytes, checksum: 7c55b1346515739af95a22eec2db0ae2 (MD5) Previous issue date: 2015 / Resumo: Este trabalho teve como objetivo a obtenção, por eletrofiação, de mantas de fibras de poli(fluoreto de vinilideno) (PVDF) sob tratamento com plasma e dispersão de nanotubo de carbono (NTC). O plasma possui a característica de tornar a superfície da manta de PVDF hidrofílica, que pode favorecer a adesão de NTC na superfície da fibra. O NTC utilizado foi previamente funcionalizado, com a presença de grupo carboxílico na superfície do tubo para que houvesse melhor afinidade entre ele e a superfície do PVDF, além disso, foi utilizado surfactante na dispersão aquosa de NTC para que se pudesse obter sua melhor distribuição e dispersão. A análise de MEV foi utilizada para estudar a morfologia das fibras, DSC para determinar a porcentagem de cristalinidade das amostras, FTIR e DRX para identificar as fases cristalinas presentes. Verificou-se pelo ensaio de condutividade elétrica que mantas tratadas com nanotubo de carbono apresentaram-se condutivas. O material obtido apresentou flexibilidade mesmo após os tratamentos com plasma e dispersão de NTC, e condutividade elétrica. A potencial aplicação em componentes eletrônicos se deve ao significativo aumento de condutividade elétrica quando a manta foi tratada em dispersão de NTC, além dos resultados mostrarem a presença de fase beta do PVDF nessas amostras. Isso se deve a uma boa distribuição e dispersão de NTC funcionalizado na estrutura superficial das fibras eletrofiadas / Abstract: In this work, fiber mats of poly(vinylidene fluoride) (PVDF) were prepared by electrospinning and suffered plasma surface treatment and immersion on carbon nanotube (CNT) dispersion. Plasma treatment can change the surface mat properties, became it through hydrophilic, which may be easier the adhesion of CNT on fiber surface. The CNT were functionalized with carboxylic group on the tube surface to became with better affinity between the nanotube and the PVDF surface, besides, surfactant was used in the CNT water dispersion to take it in a better distribution and dispersion. SEM analysis was done to evaluate the fibers morphology, DSC was to determine the samples crystallinity percentage, FTIR and XRD were to identify the crystalline phases. It was possible to ensure the conductivity at mats treated with carbon nanotubes through electrical conductivity essay. The polymeric mat showed flexibility even after the plasma and dispersion CNT treatments, besides electrical conductivity. Electronic components potential application is due to significant increase of electrical conductivity after the mat treatments, besides the results showed beta phase of PVDF in these samples. This is because of good distribution and dispersion of functionalized CNT on the surface structure of electrospun fibers / Mestrado / Materiais e Processos de Fabricação / Mestra em Engenharia Mecânica Eletrofiação Polifluoretos Nanotubos de carbono Plasma Dispersão Electrospinning Polifluoretos Carbon nanotube Plasma Dispersion
254	Nanocomposites of Multiphase Polymer Blend Reinforced with Carbon Nanotubes: Processing and Characterization WEGRZYN, MARCIN 07 April 2014 (has links) This thesis presents the study of nanocomposites based on immiscible polymer blend of polycarbonate and acrylonitrile-butadiene-styrene (PC/ABS) filled with multi-walled carbon nanotubes (MWCNT). The aim is to achieve an improvement of mechanical properties and electrical conductivity of the nanocomposites. In an initial stage, a twin-screw extruder was used to obtain nanocomposites by melt compounding. Three methods of carbon nanotubes addition were studied: direct addition, dilution from a masterbatch and feeding of MWCNT suspension in ethanol. For each method, the influence of nanofiller content and processing parameters on morphology and final properties of the nanocomposite was analyzed. Furthermore, the influence of two types of carbon nanotubes modifications was studied: covalent modification by surface-oxidation (MWCNT-COOH) and non-covalent modification by an addition of surfactant promoting the nanofiller-matrix interactions. A good dispersion of the MWCNT was obtained for masterbatch dilution and suspension feeding. Both methods showed preferential localization of carbon nanotubes in polycarbonate phase (PC). Samples processed by masterbatch dilution showed the 30 % increase of rigidity and a decrease of ductility of PC/ABS for 0.5 wt. % MWCNT. Electrical conductivity was influenced by processing temperature and carbon nanotubes type. The percolation threshold value was 2.0 wt. % for pristine MWCNT and 1.5 wt. % for modified MWCNT-COOH. Better balance of mechanical properties and electrical conductivity was achieved in the samples obtained by the masterbatch route. These properties were studied in a subsequent phase, when the extruded nanocomposite was injection molded in order to obtain a defined geometry. / Wegrzyn, M. (2014). Nanocomposites of Multiphase Polymer Blend Reinforced with Carbon Nanotubes: Processing and Characterization [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/36869 / TESIS Nanocomposite Carbon nanotube Multi-phase polymer blend Compounding Injection molding.
255	Processing Carbon Nanotube Fibers for Wearable Electrochemical Devices Kanakaraj, Sathya Narayan January 2019 (has links) No description available. Energy Carbon Nanotube Fiber Li-Ion Capacitor Nitrogen Doping Wearable Glucose Sensor Hybrid Capacitor
256	Ověřování vlastností betonů s uhlíkovými nanotrubičkami / Verification of the properties of concrete with carbon nanotubes Kutová, Lenka January 2018 (has links) This diploma thesis deals with monitoring the properties of concrete with carbon nanoparticles. The theoretical part describes properties of nanoparticles, their dosing and dispersion. In the practical part of the diploma thesis the physico-mechanical properties of the concrete with the addition of carbon nanotubes were determined after 7 and 28 days of aging. The frost resistance test was then determined after 100 cycles. All results were compared with the reference samples.
257	Functional Nanomaterials with an Electrochemistry-Based Approach to Sensing and Energy Applications Weber, Jessica Eileen 09 June 2010 (has links) In the past decade, the use of nanotechnology as a tool to develop and fabricate new structures and devices for biological sensing and energy applications has become increasingly widespread. In this work, a systematic study has been performed on one-dimensional nanomaterials, with a focus on the development of miniaturized devices with a "bottom up" approach. First, members of the nano - carbon family are utilized for biosensing applications; in particular, carbon nanotubes as well as nitrogen - doped and boron - doped nanocrystalline diamond (NCD) films. These carbon - based materials possess several unique electrochemical properties over other conductive materials which make them suitable for biosensing applications. Single walled carbon nanotubes were deposited on a glass carbon electrode and modified for the detection of Salmonella DNA hybridization. Electrochemical impedance spectroscopy (EIS) was used as the method of detection and a detection limit of 10-9 M was achieved. Nanocrystalline diamond was grown using a microwave enhanced plasma chemical vapor deposition method. The diamond electrodes were doped with either boron or nitrogen to provide substrates and characterization was performed using scanning electron microscopy, atomic force microscopy, Raman spectroscopy, Fourier transform infrared spectroscopy, UV-vis spectroscopy, as well as by electrochemical methods. Modified boron - doped NCD was able to detect Salmonella DNA hybridization via EIS and fluorescent microscopy. The detection limit for these genosensors was found to be 0.4 micrometer complementary DNA. Boron - doped and nitrogen - incorporated nanocrystalline diamond also served as functionalized electrodes for lactic acid detection. It was found that the boron - doped electrodes could detect 0.5 mM lactic acid in a phosphate buffer solution. Second, bismuth antimony nanowires were grown in an anodized alumina template for the fabrication of a thermoelectric cooling device. Bismuth antimony nanowires were chosen due to their high thermoelectric efficiency compared to their bulk material counterpart. The development of a successful anodized template was achieved and EIS was used to diagnose the optimal etch parameters of the barrier oxide layer for nanowire growth. Bismuth antimony nanowires were grown directly on a silicon substrate and a thermoelectric cooling device was fabricated. The nanowires exhibited a thermoelectric efficiency of 0.18 at room temperature. Biosensor DNA Nanocrystalline diamond Carbon nanotube Thermoelectric American Studies Arts and Humanities
258	Exploration of carbon nanotube and copper-carbon nanotube composite for next generation on-chip energy efficient interconnect applications / Exploration de nanotubes de carbone et de composites de nanotubes-cuivre pour des applications d'interconnexion sur puce de la prochained génération efficacité energitique Liang, Jie 17 June 2019 (has links) Améliorer uniquement les performances et l'efficacité énergétique des transistors n'est pas suffisant pour les futurs systèmes sur puce. Les interconnexions sont également essentielles et ont de graves répercussions sur les performances globales du circuit et l'efficacité énergétique. Le cuivre (Cu) est le matériau d'interconnexion conventionnel qui a aujourd’hui atteint ses limites par suite de l’effet de la miniaturisation. Les effets de barrière et de dispersion induisent une résistivité élevée et une forte éléctromigration aggravent la fiabilité d'interconnexion. Les Nanotubes de carbone (CNT) et les composites de Cuivre et Nanotube de carbone (Cu-CNT) sont intéressants grâce à leur transport balistique, à la grande évolutivité, à la conductivité thermique élevée et à la densité de courant élevée. Dans ce travail, nous étudions les propriétés physiques fondamentales et électriques des CNT et des composite de Cu-CNT de l’échelle atomique à l’échelle macroscopique pour les applications d’interconnexions locales et globales. Nous évaluons les différentes sources de variabilité et leurs impacts sur les performances d'interconnexion des CNT et l'efficacité énergétique. Le dopage basé sur le transfert de charge des CNT est également étudié en tant que moyen important de réduire davantage sa résistivité et d’atténuer les variations de chiralité des CNT ainsi que d’alléger les effets sur la résistance de contact. Les résultats des mesures expérimentales sont utilisés pour démontrer la validité et la précision de nos modèles établis. Les modèles d'interconnexion sont enfin appliqués aux études à l’échelle de portes et de circuits en tant qu'interconnexions locales et globales pour évaluer leurs performances. / Improving only the performance and energy efficiency of transistors is not sufficient for future systems-on-chip. On-chip interconnects have become equally critical to transistors and can detriment the system’s performance and energy efficiency. Copper (Cu) is the state-of-the-art interconnect material and is reaching its physical limitations due to scaling. Barrier and scattering effects induce high resistivity and electromigration exacerbates interconnect reliability. Carbon Nanotubes (CNTs) and Copper-Carbon Nanotube (Cu-CNT) composite materials are of interest due to ballistic transport, high scalability, high thermal conductivity, and high current density. We investigate from fundamental atomistic level to macroscopic level the physical understanding and electrical compact modeling on CNT and Cu-CNT composite for on-chip local and global interconnect applications. We evaluate and assess the different sources of variations and their impacts on CNT interconnect performance and energy efficiency. Charge transfer based doping of CNT is also investigated as an alternative method to further reduce its resistivity, mitigate CNT chirality variations and contact resistance drawbacks. Experimental measurement results are used to demonstrate the validity and accuracy of our established models. The interconnect models are finally applied to the gate- and circuit- level studies as local and global interconnects to evaluate their performance. Nanotube de carbone Interconnexion Efficacité énergétique Modélisation Simulation Nanotechnologie Carbon nanotube Interconnect Energy efficient Modeling Simulation Nanotechnology
259	Piezoresistive Behavior of Carbon Nanotube based Poly(vinylidene fluoride) Nanocomposites towards Strain Sensing Applications Ke, Kai 05 April 2016 (has links) With the development of modern industrial engineering technology, increasing demands of multifunctional materials drive the exploration of new applications of electrical conductive polymer nanocomposites (CPNCs). Toward applications of smart materials, sensing performance of CPNCs has gained immense attention in the last decade. Among them, strain sensors, based on piezoresistive behavior of CPNCs, are of high potential to carry out structural health monitoring (SHM) tasks. Poly(vinylidene fluoride) (PVDF) is highly thought to be potential for SHM applications in civil infrastructures like bridges and railway systems, mechanical systems, automobiles, windgenetors and airplanes, etc. because of its combination of flexibility, low weight, low thermal conductivity, high chemical corrosion resistance, and heat resistance, etc. This work aimed to achieve high piezoresistive sensitivity and wide measurable strain ranges in carbon nanotube based poly(vinylidene fluoride) (PVDF) nanocomposites. Four strategies were introduced to tune the sensitivity of the relative electrical resistance change (ΔR/R0) versus the applied tensile strain for such nanocomposites. Issues like the influence of dispersion of multi-walled carbon nanotubes (MWCNTs) on initial resistivity of PVDF nanocomposites and conductive network structure of MWCNTs, as well as piezoresistive properties of the nanocomposites, were addressed when using differently functionalized MWCNTs (strategy 1). In addition, the effects of crystalline phases of PVDF, mechanical ductility of its nanocomposites and interfacial interactions between PVDF and fillers on piezoresistive properties of PVDF nanocomposites were studied. Using hybrid fillers, to combine MWCNTs with conductive carbon black (strategy 2) or isolating organoclay (strategy 3), piezoresistive sensitivity and sensing strain ranges of PVDF nanocomposites could be tuned. Besides, both higher sensitivity and larger measurable strain ranges are achieved simultaneously in PVDF/MWCNT nanocomposites when using the ionic liquid (IL) BMIM+PF6- as interface linker/modifier (strategy 4). The detailed results and highlights are summarized as following: 1. The surface functionalization of MWCNTs influences their dispersion in the PVDF matrix, the PVDF-nanotube interactions and crystalline phases of PVDF, which finally results in different ΔR/R0 and the strain at the yield point (possibly the upper limit of sensing strain ranges). As a whole, regarding to the fabrication of strain sensors based on PVDF/MWCNT nanocomposite, in contrast to pristine CNTs, CNTs-COOH and CNTs-OH, CNT-NH2 filled PVDF nanocomposites possess not only high piezoresistive sensitivity but also wide measurable strain ranges. Gauge factor, i.e. GF, is ca.14 at 10% strain (strain at the yield point) for the nanocomposites containing 0.75% CNTs-NH2. 2. Using hybrid fillers of CNTs and CB to construct strain-susceptible network structure (conductive pathway consisting of string-like array of CNTs and CB particles) enhances the piezoresistive sensitivity of PVDF nanocomposites, which is tightly associated with the CNT content in hybrid fillers and mCNTs/mCB. The best piezoresistive effect is achieved in PVDF nanocomposites with fixed CNT content lower than the ΦC (0.53 wt. %) of PVDF/CNT nanocomposites. 3. ΔR/R0 and possible sensing strain ranges of PVDF nanocomposites were tailored by changing crystalline phases of PVDF and PVDF-MWCNT interactions. Besides, the increase of the strain at yield point in PVDF nanocomposites filled by CNTs-OH is more obvious than that in the nanocomposites containing the same amount of clay and CNTs. The nanocomposite consisting of 0.25% clay and 0.75% CNTs-OH have ca. 70% increase of the strain at the yield point (17%) and the GF at this strain is ca. 14, while GF for the nanocomposite filled by only 0.75% CNTs-OH is ca. 5 at 10% strain. 4. IL BMIM+PF6- served as interface linker for PVDF and MWCNTs, which significantly increased the values of ΔR/R0 and strain at the yield point of PVDF nanocomposites simultaneously. Besides, this increases with increasing IL content. With the aid of IL, the dispersion of nanotube and toughness of the nanocomposites are greatly improved, but the electrical conductivity of the nanocomposites is decreased with the incorporation of IL, which is related to the IL modified PVDF-MWCNT interface connection or bonding. GF reaches ca. 60 at 21% strain (the strain at the yield point) for PVDF nanocomposites filled by 10% IL premixed 2%CNTs-COOH. info:eu-repo/classification/ddc/540 ddc:540
260	Multifunctional composite interphase Zhang, Jie 05 June 2012 (has links) In this work, carbon nanotubes were deposited onto the insulative glass fibre surface to form a semiconductive network. Utilizing the unique properties of CNTs network, a multifunctional composite interphase could be achieved. The interfacial adhesion strength was improved by CNTs distributed in the interphase. The semiconductive interphase have been used as a chemical/phaysical sensor, strain sensor and microswitch. info:eu-repo/classification/ddc/620 ddc:620 Multifunktionale Grenzschicht

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