Global ETD Search

71	Facile Fabrication of Functionally Graded Graphene Films for Transient Electronics Bhatkar, Omkar S. January 2018 (has links) No description available. Mechanical Engineering Materials Science Nanotechnology Chemistry graphene transient electronics graphene oxide metals film fabrication deposition reduction reduced graphene oxide RFID actuators humidity sensors
72	NOVEL BIOBASED CHITOSAN/POLYBENZOXAZINE CROSS-LINKED POLYMERS AND ADVANCED CARBON AEROGELS FOR CO2 ADSORPTION Alhwaige, Almahdi A. 11 June 2014 (has links) No description available. Chemical Engineering Clay graphene oxide chitosan polybenzoxazine graphene oxide cross-linked polymers nanocomposites aerogels CO2 adsorption adsorption isotherms diffusion in porous media and CO2 adsorption thermodynamics
73	The first order Raman spectrum of isotope labelled nitrogen-doped reduced graphene oxide Dahlberg, Tobias January 2016 (has links) The topic of this thesis is the study of nitrogen functionalities in nitrogen-doped reduced graphene oxide using Raman spectroscopy. Specifically, the project set out to investigate if the Raman active nitrogen-related vibrational modes of graphene can be identified via isotope labelling. Previous studies have used Raman spectroscopy to characterise nitrogen doped graphene, but none has employed the method of isotope labelling to do so. The study was conducted by producing undoped, nitrogen-doped and nitrogen-15-doped reduced graphene oxide and comparing the differences in the first-order Raman spectrum of the samples. Results of this study are inconclusive. However, some indications linking the I band to nitrogen functionalities are found. Also, a hypothetical Raman band denoted I* possibly related to \spt{3} hybridised carbon is introduced in the same spectral area as I. This indication of a separation of the I band into two bands, each dependent on one of these factors could bring clarity to this poorly understood spectral area. As the results of this study are highly speculative, further research is needed to confirm them and the work presented here serves as a preliminary investigation. graphene reduced graphene oxide reduced graphite oxide nitrogen doping raman spectroscopy isotope labelling
74	Investigation of Graphene Formation from Graphite Oxide and Silicon Carbide Sokolov, Denis A. 05 February 2013 (has links) Graphene is a novel two dimensional material that is revolutionizing many areas of science and it is no surprise that a significant amount of effort is dedicated to its investigation. One of the major areas of graphene research is the development of procedures for large scale production. Among many recently developed methodologies, graphene oxide reduction stands out as a straightforward and scalable procedure for producing final material with properties similar to those of graphene. Laser reduction of graphite oxide is one of the novel approaches for producing multilayer graphene, and this work describes a viable approach in detail. It is determined that a material which is comprised of a combination of laser reduced graphite oxide-coupled to an unreduced graphite oxide layers beneath it, produces a broadband photosensitive material. The efficiency of light conversion into electrical current is greatly dependent upon the oxygen content of the underlying graphite oxide. Developing novel ways for reducing graphite oxide is an ongoing effort. This work also presents a new method for achieving complete reduction of graphite oxide for producing predominantly sp2 hybridized material. This approach is based on the irradiation of graphite oxide with a high flux 3 keV Ar ion beam in vacuum. It is determined that the angle of irradiation greatly influences the final surface morphology of reduced graphite oxide. Also, multilayer epitaxial graphene growth on silicon carbide in ultra-high vacuum was investigated with quadrupole mass spectrometry (QMS). Subliming molecular and atomic species were monitored as a function of temperature and heating time. The grown films were characterized with X-ray photoelectron spectroscopy coupled with Ar ion depth profiling. SiC epitaxy Raman XPS SEM Ion reduction QMS Light sensor Laser reduction Graphite oxide Graphene oxide
75	Formation Mechanisms and Photocatalytic Properties of ZnO-Based Nanomaterials Herring, Natalie 18 April 2013 (has links) Zinc Oxide (ZnO) is one of the most extensively studied semiconductors because of its unique properties, namely, its wide band gap (3.37 eV) and high excitation binding energy (60 meV). These properties make ZnO a promising material for uses in a broad range of applications including sensors, catalysis and optoelectronic devices. The presented research covers a broad spectrum of these interesting nanomaterials, from their synthesis and characterization to their use as photocatalyts. A new synthetic approach for producing morphology controlled ZnO nanostructures was developed using microwave irradiation (MWI). The rapid decomposition of zinc acetate in the presence of a mixture of oleic acid (OAC) and oleylamine (OAM) results in the formation of hexagonal ZnO nanopyramids and ZnO rods of varying aspect ratios. The factors that influence the morphology of these ZnO nanostructures were investigated. Using ligand exchange, the ZnO nanostructures can be dispersed in aqueous medium, thus allowing their use as photocatalysts for the degradation of malachite green dye in water. Photocatalytic activity is studied as a function of morphology; and, the ZnO nanorods show enhanced photocatalytic activity for the degradation of the dye compared to hexagonal ZnO nanopyramids. After demonstrating the catalytic activity of these ZnO nanostructures, various ways to enhance photocatalytic activity were studied by modification of this MWI method. Photocatalytic activity is enhanced through band gap modulation and the reduction of electron-hole recombination. Several approaches were studied, which included the incorporation of Au nanoparticles, N-doping of ZnO, supporting ZnO nanostructures on reduced graphene oxide (RGO), and supporting N-doped ZnO on N-doped RGO. ZnO-based nanostructures were studied systematically through the entire process from synthesis and characterization to their use as photocatalysis. This allows for a thorough understanding of the parameters that impact these processes and their unique photocatalytic properties. ZnO Reduced graphene oxide Microwave Irradiation Photocatalysis Au-ZnO N-doping Chemistry Physical Sciences and Mathematics
76	Ultra-sensitive carbon based molecular sensors Huang, Jingfeng January 2015 (has links) This thesis presented the study of carbon-based materials for ultra-sensitive molecular sensing. Reduced Graphene Oxide (rGO), a 2-dimensional one-atomic layer thick carbon material, had the advantage of low-cost, aqueous and industrial-scalable production route. Using rGO as the transducer platform could potentially lower the cost of sensors down to a few dollars per chip. However, there were still limitations in rGO that prevented its widespread usage as a biosensor transducer or in electronics: its low electrical conductivity and large electrical deviations. This thesis was structured to understand and solve these problems for transducer application. The thesis could be broken down into 3 parts: The first part of the thesis presented the critical review of the background and limitations of graphene research, followed by the background and importance of biosensor developments for the detection of sweat sodium ions and circulatory Interleukin-6 proteins. The second part of the thesis tested the hypothesis that the rGO limitations could be eliminated to create a highly sensitive biosensor transducer via (A) improving rGO synthesis (B) pristine Carbon Nanotubes-rGO hybrid film and (C) growth of rGO. The mechanism of ultra-large graphene oxide synthesis and graphene oxide growth was also elucidated in this section. The third part of the thesis then presented the fabrication and test of the practical and homogenous carbon-based biosensor using the transducer synthesized earlier. The thesis showed that through proving the hypothesis correct, it enabled the synthesis of an all organic sodium ion sensor with integrated pump and an ultra-sensitive interleukin-6 bio-sensor. Both of these novel sensors were able to detect the respective molecules in their physiological ranges. 610.28
77	Tribological Behaviour of Hybrid Carbon Filled UHMWPE Composites in Water Vadivel, Hari Shankar January 2016 (has links) There is a increasing emphasis in today’s world to use environmental friendly solutions for tribological and lubrication purposes. Use of water as a lubricant presents a cost effective and easy method of bio friendly lubrication. But, as water has low viscosity, it is necessary that the materials used in water lubricated contacts perform exceedingly well in boundary lubricated conditions. Polymer Based Materials (PBMs), are one such group of materials which have been proven to perform well in such conditions. In particular, Ultra High Molecular Weight Polyethylene (UHMWPE) has been extensively used in water lubricated contacts. But, PBMs still suffer from wear and related problems and there is room for improvement. Various methods have been tried with mixed results to improve the qualities of polymers and consequently their performance in water lubricated contacts. One such method is by inclusion of fillers. Conventionally, micron sized fillers have been used to form composites with a polymer resulting in materials with better properties. Recently, nanometer sized reinforcements have been attracting more attention due to their unique mechanical and tribological properties. Combining micrometer and nanometer sized filler in a polymer composite could help form materials with excellent properties. Such composites would be termed as a hybrid material. Therefore, the aim of this project and thesis is to experimentally investigate the influence and interaction of micro and nano carbon-based fillers on tribological behaviour of UHMWPE composites and provide further understanding of the mechanisms involved. UHMWPE Tribology Carbon fillers Water Nanodiamond Graphene Oxide Short Carbon fibre Friction Wear
78	Estudo da utilização do óxido de grafeno e do óxido de grafeno imobilizado em matriz de poli(divinilbenzeno) visando o tratamento de rejeito radioativo líquido contendo césio-137 / Study of the use of graphene oxide and immobilized graphene oxide in poly(divinylbenzene) matrix for the treatment of liquid radioactive waste containing cesium-137 Oliveira, Fernando Mendes de 17 December 2018 (has links) O óxido de grafeno (OG), nanomaterial sintetizado a partir do grafite, tem atraído atenção como adsorvente com grande capacidade de remoção de cátions e diversos contaminantes de soluções aquosas, devido a presença dos grupos hidroxila, epóxi, carbonila e carboxila em sua superfície. Este trabalho, visa avaliar o potencial do óxido de grafeno bruto (OG) e de sua forma imobilizada em poli(divinilbenzeno) (PDVB-OG) na remoção de íons de césio de uma solução aquosa sintética. Os experimentos foram realizados em batelada, e foi avaliado a influência do tempo de contato e da concentração inicial de íons de césio. Para descrever a isotermas de equilíbrio foram aplicados os modelos de Langmuir e Freundlich, e a cinética do processo de adsorção, foi avaliada utilizando-se os modelos de pseudo-primeira ordem, pseudo-segunda ordem e difusão intrapartícula. Para prever a espontaneidade do processo de adsorção, foi calculado a energia livre de Gibbs. Nos experimentos de adsorção de íons de césio, o OG e o nanocompósito PDVB-OG, após 30 min. de contato, apresentaram taxa de remoção de 80% e 63% respectivamente. O modelo que melhor descreveu o processo de adsorção, para ambos adsorventes, na faixa de concentração de 30 a 130 mg.L-1, foi o de Langmuir e a capacidade máxima de adsorção calculada foi de 17 mg.g-1 para o OG e de 15 mg.g-1 para o PDVB-OG. Tanto para o OG quanto para o PDVB-OG, o modelo cinético que melhor descreveu o processo foi o de pseudo-segunda ordem e o valor da energia livre de Gibbs determinou que a adsorção dos íons de césio foi espontânea. A matriz polimérica não apresentou capacidade de remoção significativa, evidenciando que a adsorção dos íons césio pelo nanocompósito de PDVB-OG se deve a presença do OG imobilizado. Por outro lado, devido a maior densidade, o PDVB-OG foi facilmente separado da solução por decantação após o experimento de adsorção. Os resultados indicam a capacidade do OG e do nanocompósito PDVB-OG em tratar rejeitos líquidos radioativos, a fim de minimiza-los. / Due to the presence of hydroxyl, epoxy, carbonyl and carboxyl groups on its surface, graphene oxide (GO), synthesized from graphite, has attracted attention as a high adsorbent of cation removal and several contaminants from aqueous solutions. This work aims to evaluate the potential of graphene oxide (GO) and its immobilized form as poly(divinylbenzene) (PDVB-GO) in the removal of cesium ions from a synthetic aqueous solution. The experiments were performed in batch, and the influence of the contact time and the initial concentration of cesium ions were studied. Langmuir and Freundlich models as the equilibrium isotherms, and the kinetics of the adsorption process, pseudo-first order, pseudo-second order and intraparticle diffusion models, were evaluated GO and PDVB-GO, removed after 30 min. of contact time 80% and 63% of cesium ion, respectively for both adsorbents. The maximum adsorption capacities were 17 mg.g-1 for the GO and 15 mg.g-1 for the PDVB-GO. For both GO and PDVB-GO, Langmuir model fitted better in the adsorption process, the Gibbs Free Energy showed that this process for were spontaneous and the kinetic models were the pseudo-second order. As the polymer matrix, PDVB, has no significant removal capacity, the adsorption of the cesium ions by the PDVB-GO nanocomposite is due to the presence of the GO. On the other hand, the PDVB-GO was easily separated from the solution by decantation after the adsorption experiment. The results indicate the ability of the GO and the PDVB-GO nanocomposite to treat radioactive liquid wastes in order to minimize them. adsorção adsorption césio cesium graphene oxide nanocomposite nanocompósito óxido de grafeno poli(divinilbenzeno) poly(divinylbenzene)
79	Oxidação eletroquímica do etanol em eletrólito alcalino utilizando nanocompósito a base de grafeno/paládio / Electrochemical oxidation of ethanol in alkaline electrolyte using graphene / palladium base nanocomposite Ferreira Sobrinho, Luiza 13 December 2018 (has links) Nesse estudo foi sintetizado e caracterizado o óxido de grafeno (OG) a partir do método de Hummers modificado. O OG foi utilizado como suporte para nanopartículas de paládio para uso como eletrocatalisador em células a combustíveis abastecidas diretamente a etanol. O uso de carbono grafite como suporte de nanopartículas metálicas é deteriorado com mais rapidez, levando a diminuição do tempo de vida útil da célula a combustível. O objetivo principal foi a incorporação do paládio no óxido de grafeno via feixe de elétrons, e a comparação com o catalisador incorporado por via química, utilizando o borohidrato de sódio. Foram utilizadas técnicas de caracterização tais como: termogravimetria (TG), difração de raios-X (DRX), as espectroscopias de Raman e infravermelho com transformada de Fourier (FT-IR), microscopia de transmissão eletrônica (MET), Espectroscopia de fotoelétrons por raios- X (XPS) e estudos voltamétricos como a voltametria cíclica e cronoamperometria. Os resultados indicaram que para a dose de 288 kGy, houve a incorporação, porém, não foi suficiente para que houvesse a redução dos grupos oxigenados, estudos com o oxido de grafeno previamente reduzido via térmica e incorporado via feixe de elétrons foram comparados na mesma dose. / In this study, graphene oxide (GO) was synthesized by the modified Hummers method and characterized. GO was used as support for palladium nanoparticles as an electrocatalyst on direct ethanol fuel cell (DEFC). One of the drawbacks using carbon graphite as a support for metal nanoparticles was because it deteriorates more quickly, leading to shortened fuel cell life. The main objective was the incorporation of Pd on the graphene oxide by the electron beam and was compared with the chemical incorporation, using sodium borohydride. Characterization techniques such as thermogravimetry (TG), X-ray diffraction (XRD), Raman spectroscopy and Fourier transform infrared (FT-IR), electron transmission microscopy (TEM), X-ray photoelectron spectroscopy (XPS) and voltammetric studies such as cyclic voltammetry and chronoamperometry. The results indicated that at a dose of 288 kGy, there was an incorporation, however, it was not enough for there to be a decrease in the groups of oxygenates, studies with the graphene oxide downloaded through the thermal and through electron beams were compared in the same dose. célula à combustível cyclic voltammetry fuel cell graphene oxide óxido de grafeno paládio palladium voltametria cíclica
80	Mecanismos de condução em filmes nanoestruturados de óxidos de grafeno / Conducting mechanisms in nanostructured films of graphene oxides Martinez Jimenez, Mawin Javier, 1985- 06 November 2017 (has links) Orientador: Antonio Riul Júnior / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-09-02T19:37:47Z (GMT). No. of bitstreams: 1 Jimenez_MawinJavierMartinez_D.pdf: 7578838 bytes, checksum: def5bc65d8270856f55d63211e1e0f09 (MD5) Previous issue date: 2017 / Resumo: Para alcançar alto desempenho em dispositivos e aplicações faz-se necessário uma melhor compreensão do comportamento de materiais a base de grafeno em nanoescala para otimização de design e fabricação. A síntese química é uma excelente rota alternativa para produzir compósitos em nanoestruturas bem definidas de tamanhos semelhantes, garantindo propriedades elétricas reprodutíveis para aplicações confiáveis. O grafeno, na forma de pontos quânticos (QDs, do inglês quantum dots) em dimensão zero e nanofolhas (NPLs, do inglês graphene nanoplateletes) bidimensionais (2D), são materiais emergentes com funcionalidades únicas promissoras para novas aplicações. Neste trabalho apresentamos um estudo detalhado dos mecanismos de transporte em nanoestruturas formadas pela técnica de automontagem por adsorção física (LbL, do inglês Layer-by-Layer) na forma de multicamadas, com controle de espessura em nível molecular. Os filmes LbL foram formados por óxido de grafeno reduzido (rGO) funcionalizado com diferentes polieletrólitos tanto na forma de QDs quanto nanofolhas. As caracterizações elétricas indicaram corrente limitada pela carga espacial em algumas amostras, e em outras arquiteturas moleculares, mecanismo de condução via Poole-Frenkel seguindo a lei de Mott dominada por saltos variáveis. A flexibilidade da técnica LbL aliada à dimensão dos materiais utilizados foram favoravelmente exploradas como um ajuste fino para controle da mobilidade de portadores dentro das nanoestruturas formadas. Foi observado em alguns casos uma condução planar no interior da camada contendo rGOs na estrutura LbL com mobilidade eletrônica efetiva de ~ 35 cm² V^-1 s^-1. Em outros casos um mecanismo de condução 3D (interplanar ao longo de toda nanoestrutura LbL) com mobilidade eletrônica de ~ 151 cm² V^-1 s^-1. Medidas em função da temperatura indicaram alta probabilidade de saltos randômicos entre ilhas condutoras de rGO distribuídas ao longo da camada contendo os pontos quânticos, que contribui para um maior tempo de trânsito dos portadores e, consequentemente, mobilidades menores. O oposto ocorre para as nanofolhas de rGO, que requerem maiores energias de ativação devido ao tamanho e presença de defeitos, resultando em caminhos condutores maiores e com maiores mobilidades / Abstract: To achieve high-performance in devices and applications it is important a better comprehension of the behavior at nanoscale of graphene-based materials to promote a rational design and fabrication. The chemical synthesis is an excellent alternative route to optimize graphene-based composites in well-defined nanostructures of similar sizes, ensuring reproducible electrical properties for reliable applications. Graphene as quantum dots (QDs) and nanoplatelets (NPLs) presents emerging zero- and two-dimensional (2D) materials with promising unique functionalities to novel applications. We present here a detailed study of the charge transport mechanisms in multilayered nanostructures formed by physical adsorption through the layer-by-layer (LbL) technique, with molecular level thickness control. The LbL films were formed by reduced graphene oxides (rGO) functionalized with different polyelectrolytes and processed either as QDs or nanoplatelets. The electrical characterizations indicated a space-charge-limited current (SCLC) in some samples, while in other molecular architectures it was found a Poole-Frenkel conduction mechanism dominated by a Mott-variable range hoping model. The LbL assembly together with the dimensionalty of the materials could be favorably used as a fine tuning to control the charge carrier mobility inside the formed nanostructures. The flexibility of the LbL technique together with the dimensionality of the materials were favorably explored as a fine tuning of the charge carrier mobility inside the nanostructures. It was observed in some cases a 2D intra-planar conduction within the rGO layer in the LbL films, with an effective charge carrier mobility of ~ 35 cm² V-1 s-1, and in other cases a 3D conduction mechanism (interplanar along with the LbL nanostructure) with electronic mobility of ~ 151 cm² V-1 s-1. Temperature measurements indicated a higher probability of random jumps between rGO conducting "islands" distributed along with the plane layer having quantum dots, which contributes for a longer transit time of the carriers and, consequently, lower mobility values. The opposite occurred for the rGO nanoplatelets that required higher activation energy due to size and presence of defects, resulting in larger conductive pathways and higher mobilities / Doutorado / Física / Doutor em Ciências / 1247719 / CAPES / FAPESP Nanomateriais Filmes multicamadas Óxido de grafeno Nanomaterials Layer-by-layer films Graphene oxide

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