Global ETD Search

41	Synthesis, Characterization, Chemical Reduction and Biological Application of Graphene Oxide Gao, Xiguang 06 November 2014 (has links) As an atomic layer of sp2-hybridized carbon atoms closely packed in a honeycomb lattice, graphene has been attracting increasing attention since its discovery in 2004 due to its extraordinary physicochemical properties. Graphene oxide (GO), a non-stoichiometric graphene derivative with the carbon plane abundantly decorated with hydroxyl, epoxide and carboxylic groups, can be massively and cost-effectively produced from natural graphite following Hummers method. GO has greater aqueous solubility than pristine graphene due to its oxygen-functionalities. Various solution-based chemical methods can be applied to GO, which has stimulated a new research area called ???wet chemistry of grahene???. Among them, chemical reduction of GO provides a facile route for large-scale synthesis of graphene. With abundant oxygen-functionalities in its structure, GO can potentially act as a suitable precursor for chemical modifications of graphene through methods used in organic chemistry. Special attention should be paid to that the hydroxyl groups in GO belong to tertiary alcohols, and steric hindrance should be considered when performing chemical modifications. Diethylaminosulfur trifluoride (DAST), a fluorinating reagent, is ineffective in fluorinating GO due to the steric hindrance of tertiary hydroxyls. However, DAST is effective in reducing GO. The capability of DAST for GO reduction is close to hydrazine, but the reduction reaction can be performed at lower temperature for DAST. As a two-dimensional (2D) nanomaterial with good aqueous solubility, biocompatibility and excellent intrinsic mechanical properties, GO is particularly useful in preparing 3D hybrid hydrogel scaffolds for tissue engineering applications. graphene oxide synthesis characterization reduction fluorination tissue engineering
42	Fabrication of 3D Hybrid Architectures Composed of sp2-Carbon and Inorganic Materials Mazloumi Sadat, Seyed Mahyar 30 September 2013 (has links) Three dimensional (3D) hybrid architectures are new types of materials that have a number of technological applications. However, the synthesis of such materials has been problematic to date. The objective of this study is to fabricate 3D hybrid architectures composed of sp2-carbon nanomaterials and inorganic nanostructures using a convenient microwave assisted technique. Sp2-Carbon nanomaterials such as carbon nanotubes (CNTs), graphene and its derivative graphene oxide (GO), have been explored by researchers as major components of hybrid materials due to their exceptional electrical, thermal, mechanical and biological properties. However, most of the research has been devoted to the hybrids with randomly dispersed phases. The present study explores the feasibility of using aligned 3D sp2-carbon structures in a bottom-up microwave-assisted chemical synthesis approach to fabricate various 3D sp2-carbon/inorganic hybrid architectures. The carbon nanostructures, either tubular or planar, not only contribute to the functionalities of the hybrids, but also template the ordered assembly of phases on nanometer scale. Mimicking nature is a key to develop novel types of materials with enhanced physical and mechanical properties suitable for advanced applications (e.g. lightweight and yet tough materials that are extensively needed in automotive and aerospace industries). One approach to obtain such materials or devices is to mimic nature processes and synthesize hybrid materials with ordered structures on the nanometer scale. Those functional structures are fabricated in this thesis through an in-situ microwave synthesis of inorganic materials on 3D sp2-carbon architectures. Generally, in chapter 1, it was shown and discussed the procedures to fabricate 3D architectures of carbon nanotubes and graphene oxide as basic components for template synthesis of the hybrids. Then in chapter 2 the microwave chemical synthesis approach was introduced as a convenient route for fabricating inorganic materials such as zinc oxide (ZnO) which was shown to be used as UV sensors. Through photolithography patterning of the iron catalyst thin films on Si/SiO2 substrates, 3D aligned CNT structures were fabricated and were coated in-situ with inorganic materials such as cobalt oxide, zinc oxide and manganese oxide using a microwave synthesis approach (chapter 3). The obtained aligned strips of CNT/Co3O4 were chosen as an example to illustrate the application of such 3D hybrids in energy storage applications. The capacitance of the aligned CNT/Co3O4 strips was measured to be 123.94 F/g. Using graphene oxide as template for manufacturing the 3D sp2-carbon/inorganic hybrid structures, interesting novel layered configurations are obtained that are similar to the layered structures of exoskeleton of the mollusks nacre. The layered hybrid structure shown to be mechanically improved compared to its constituents (chapter 4). Finally in chapter 5, some of the future routes have been proposed for further research on this novel field of 3D hybrid materials composed of sp2-carbons and inorganic nanomaterials. Hybrid Materials Carbon Nanotube Graphene Oxide Inorganic Materials
43	A Study on Nano-Si/Polyaniline/Reduced Graphene Oxide Composite Anode for Lithium-Ion Batteries Li, Kai January 2013 (has links) Because of its high theoretical specific capacity (4200mAh/g) and natural abundance (2nd most abundant element on earth), silicon is considered a promising anode candidate for high energy density lithium-ion batteries. However, the dramatic volume changes (up to 400%) that occur during lithiation/delithiation and the relative low electrical conductivity of silicon prevent the implementation of this material. In this work, a nano-silicon/polyaniline/reduced graphene oxide composite was synthesized via a two-step process: in-situ polymerization of polyaniline (PANi) in the presence of nano-silicon followed by combination of the prepared n-Si/PANi binary composite with reduced graphene oxide (RGO), to form a n-Si/PANi/RGO composite. Electron microscopy reveals the unique nano-architecture of the n-Si/PANi/RGO composite: silicon nanoparticles are well dispersed within a PANi matrix, which in turn is anchored to the surface of RGO sheets. The n-Si/PANi/RGO ternary composite delivered an initial capacity of 3259 mAh/g and 83.5% Coulombic efficiency. The new composite displayed better rate performance and capacity recovery than either nano-Si or n-Si/PANi. Structural and morphological studies combined with AC impedance analysis suggest that the n-Si/PANi/RGO composite has higher electrical conductivity than the other two component materials, yielding better performance at high current densities or C rates. The good rate performance, high initial specific capacity and stable Coulombic efficiency of n-Si/PANi/RGO make it a promising anode material for high energy density lithium-ion batteries. Lithium-ion Batteries polyaniline reduced graphene oxide Chemical Engineering
44	A Study on Nano-Si/Polyaniline/Reduced Graphene Oxide Composite Anode for Lithium-Ion Batteries Li, Kai January 2013 (has links) Because of its high theoretical specific capacity (4200mAh/g) and natural abundance (2nd most abundant element on earth), silicon is considered a promising anode candidate for high energy density lithium-ion batteries. However, the dramatic volume changes (up to 400%) that occur during lithiation/delithiation and the relative low electrical conductivity of silicon prevent the implementation of this material. In this work, a nano-silicon/polyaniline/reduced graphene oxide composite was synthesized via a two-step process: in-situ polymerization of polyaniline (PANi) in the presence of nano-silicon followed by combination of the prepared n-Si/PANi binary composite with reduced graphene oxide (RGO), to form a n-Si/PANi/RGO composite. Electron microscopy reveals the unique nano-architecture of the n-Si/PANi/RGO composite: silicon nanoparticles are well dispersed within a PANi matrix, which in turn is anchored to the surface of RGO sheets. The n-Si/PANi/RGO ternary composite delivered an initial capacity of 3259 mAh/g and 83.5% Coulombic efficiency. The new composite displayed better rate performance and capacity recovery than either nano-Si or n-Si/PANi. Structural and morphological studies combined with AC impedance analysis suggest that the n-Si/PANi/RGO composite has higher electrical conductivity than the other two component materials, yielding better performance at high current densities or C rates. The good rate performance, high initial specific capacity and stable Coulombic efficiency of n-Si/PANi/RGO make it a promising anode material for high energy density lithium-ion batteries. Lithium-ion Batteries polyaniline reduced graphene oxide Chemical Engineering
45	Síntese e caracterização de grafeno oxidado e nanofitas de carbono e estudos de susas possíveis aplicações RODRÍGUEZ, Blanca Azucena Gómez 08 April 2015 (has links) Submitted by Fabio Sobreira Campos da Costa (fabio.sobreira@ufpe.br) on 2016-08-18T15:18:04Z No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) TESE-BAGR.pdf: 9049017 bytes, checksum: af3edd6dce7e702e64d600bace79a1e9 (MD5) / Made available in DSpace on 2016-08-18T15:18:04Z (GMT). No. of bitstreams: 2 license_rdf: 1232 bytes, checksum: 66e71c371cc565284e70f40736c94386 (MD5) TESE-BAGR.pdf: 9049017 bytes, checksum: af3edd6dce7e702e64d600bace79a1e9 (MD5) Previous issue date: 2015-04-08 / CNPq / Atualmente o grafeno tem sido considerado uma nanoestrutura ideal para diversas aplicações, porém o processo de síntese em longa escala ainda é um desafio, sendo o grafeno oxidado (GO) uma possível solução para obter o grafeno em grande quantidade. Neste trabalho sintetizamos GO utilizando método de Hummers ao qual introduzimos modificações de modo a diminuir os gases tóxicos produzidos durante a síntese. De modo a não alterar as propriedades do grafeno devido à introdução de grupos funcionais existentes no GO utilizamos dois processos de redução, um químico e outro térmico. O grafeno obtido por ambos processos foi caracterizado do ponto de vista estrutural, morfológico e óptico. Os resultados revelaram que o grafeno reduzido (RGO) apresentava na forma de bicamada, com uma alta área superficial (500 m2 g-1). Foi observado também no espectro UV-Vis, um deslocamento de comprimento de onda da ordem de 40 nm para energias maiores e uma diminuição de 50% do número de defeitos em relação ao GO, devido a eliminação de grupos funcionais, pelo processo de redução. Utilizamos o mesmo processo de síntese do RGO para produzir nanofitas de carbono. As nanofitas apresentam propriedades similares ao grafeno, embora estas não dependam somente do número de folhas, como no caso do grafeno. As propriedades elétricas das nanofitas dependem fortemente de sua largura. Assim, para o controle da largura das nanofitas, utilizamos o método de Tour para a abertura de nanotubos de carbono de múltiplas camadas (MWCNTs). As nanofitas sintetizadas possuem comprimentos em torno de 5 μm e larguras em torno de 150 nm, e com número de folhas menor ou igual a 5. Além da síntese do grafeno e das nanofitas utilizamos nanopartículas magnéticas para decorar estas nanoestruturas, visando obter materiais com propriedades catalíticas, magnéticas e biocompatíveis. Utilizamos essas nanoestruturas para estudar suas possíveis aplicações no desenvolvimento de capacitores, na remoção de corantes e como sensor de biomoléculas. / Synthesis and characterization of graphene oxide and graphene nanoribbons Due to its excellent properties graphene has been established as a very good candidate in many potential applications. However, one of the main challenge for achivieving that is the massive producution of this material. Graphene oxide (GO) has been suggested as a possible route to face this concern taking the great advantage of its large scale production. In this work, we synthetise GO using the well-known Hummers method with some modifications in order to reduce the production of toxic gases. Futhermore, reduction of GO was performed to keep physical properties to be the most closest to graphene by eliminating funtional groups attached to the GO. Then, the obtained reduced graphene oxide (RGO) was characterized structural and morphologically. Those studies reveal that the RGO has at least 2 sheets, a high surface area (500 m2g-1) and a reduction of defects very close to a half of that in GO. Synthesis of graphene nanoribbons was also explored using the Tour procedure. Our results suggest the sucessful synthesis of nanoribbons with typical dimensions of 5 um in length, witdth of 150 nm and composed of less than 5 sheets. Decoration of graphene and graphene nanorribons with magnetic particles was achieved to study biocompatibility, catalityc and magnetic properties. Finally, some applications with the synthetized materials are developed in the field of capacitors, colorant removal and biosensors. Nanoestruturas Grafeno Grafeno oxidado Nanofitas de carbono Nanostructures Graphene oxide Nanoribbons
46	Estudo do processo de redução térmica em vácuo do óxido de grafeno visando à obtenção de matéria-prima para supercapacitor / Study of the process of thermal reduction in vacuum of the graphene oxide for obtaining starting material for supercapacitor Quezia de Aguiar Cardoso Ribeiro 24 April 2017 (has links) Neste estudo foi investigado o processo de redução térmica do óxido de grafeno em médio vácuo como uma rota viável de baixo custo econômico para obtenção do óxido de grafeno reduzido para aplicação em supercapacitores. O objetivo principal foi estudar a influência da temperatura de processamento no grau de redução do óxido de grafeno utilizando um sistema de vácuo com bomba mecânica de duplo estágio. O processamento constituiu na exposição do óxido de grafeno em várias temperaturas (200, 400, 600, 800 e 1000 °C) com pressão reduzida (10-2mbar) condição de médio vácuo. Foram utilizadas técnicas convencionais para caracterização dos materiais precursores e processados, tais como: microscopia eletrônica de varredura (MEV), difração de raios-X (DRX) e espectroscopia no infravermelho com transformada de Fourier (FTIR). Com os resultados deste estudo foi demostrado que é possível obter o óxido de grafeno reduzido utilizando um sistema de vácuo com bomba mecânica de duplo estágio e temperaturas de processamento superiores a 200°C. / In this study the process of medium vacuum thermal reduction of the graphene oxide as a low cost route for obtaining reduced graphene oxide has been investigated. The main objective was to study the influence of the processing temperature on the degree of reduction of the graphene oxide using a vacuum system with two stage backing pump. The processing was carried out by exposing the graphene oxide at various temperatures (200, 400, 600, 800 e 1000 °C) with reduced pressure (10-2 mbar). Conventional techniques have been employed to the characterization of the starting and processed materials, such as: scanning electron microscopy (SEM), X-ray diffraction and Fourier transformed infrared spectroscopy (FTIR). With the results of this study it has been demonstrated that it is possible to obtain the reduced graphene oxide using a vacuum system with a two stage backing pump and processing temperatures superior to 200°C. grafeno redução do óxido de grafeno supercapacitores graphene reduction of graphene oxide supercapacitors
47	Fabrication and characterisation of electrospun polyvinylidene fluoride (PVDF) nanocomposites for energy harvesting applications Song, Hang January 2016 (has links) Three systems of electrospun composite membranes with piezoelectric polymer polyvinylidene fluoride (PVDF) as matrix incorporating: 1) Carbon based fillers: carbon nanotube (CNT) and graphene oxide (GO); 2) Ceramic based fillers-barium titanate (BT), zinc oxide (ZnO) and nanoclays (halloysite and bentonite); 3) Cellulosic fillers: microcrystalline cellulose (MCC) and nanocrystalline cellulose (NCC) at different loadings were prepared by electrospinning process. Influence of filler type and loading on total PVDF crystallinity (Xc), relative fraction of β phase (piezoelectric phase) in total crystalline PVDF (Fβ), volume fraction of β phase in the samples (vβ) and piezoelectric coefficient d33 were characterised and analysed. Correlation between vβ and piezoelectric performance (d33) will be focused by this work. A common situation was observed for the composites-d33 increased while vβ is reduced by the fillers, so it can be concluded that d33 of the composites is not totally up to their vβ, there are other factors that need to be taken into account. For example, for carbon based filler like CNT, it increased electric conductivity of sample during and after electrospinning process, making it easier for charges produced by β crystals from inside of sample to be transferred to surfaces of the sample, and possibly promoting orientation of β crystals in d33 direction, therefore enhanced d33 of the composites though β phase formation was significantly hindered by inclusion of CNT; For piezoelectric ceramic fillers like BT and ZnO, a possible combined piezoelectricity from filler and β phase PVDF might enhanced d33 though less β phase was formed; And for non-piezoelectric and non-conductive fillers, enhancement in orientation of β crystals might play a major role in promotion of d33. Keywords: electrospinning; polyvinylidene fluoride (PVDF); nanocomposites; piezoelectric coefficient d33; energy harvesting. 621.38
48	Preparation of Reduced Graphene Oxides as Electrode Materials for Supercapacitors Bai, Yaocai 06 1900 (has links) Reduced graphene oxide as outstanding candidate electrode material for supercapacitor has been investigated. This thesis includes two topics. One is that three kinds of reduced graphene oxides were prepared by hydrothermal reduction under different pH conditions. The pH values were found to have great influence on the reduction of graphene oxides. Acidic and neutral media yielded reduced graphene oxides with more oxygen-functional groups, lower specific surface areas but broader pore size distributions than those in basic medium. Variations induced by the pH changes resulted in great differences in the supercapacitor performance. The graphene produced in the basic solution presented mainly electric double layer behavior with specific capacitance of 185 F/g, while the other two showed additional pseudocapacitance behavior with specific capacitance of 225 F/g (acidic) and 230 F/g (neutral), all at a constant current density of 1A/g. The other one is that different reduced graphene oxides were prepared via solution based hydrazine reduction, low temperature thermal reduction, and hydrothermal reduction. The as- prepared samples were then investigated by UV-vis spectroscopy, X-ray diffraction, Raman spectroscopy, and Scanning electron microscope. The supercapacitor performances were also studied and the hydrothermally reduced graphene oxide exhibited the highest specific capacitance. Supercapacitor Hydrothermal Specific Capacitance Functionalization Graphene Reduced graphene oxide
49	Removing heavy metals from wastewater using graphene oxide Wang, Ying January 2021 (has links) Heavy metals in wastewater can cause serious environmental problems and could beharmful to the human body. Therefore, heavy metals need to be removed from thewastewater. Coagulation based methods are popularly used nowadays with provedeffects. New methods such as the application of nanomaterials have brought morepossibilities to increase the removal effects for certain heavy metals. Among thesenanomaterials, graphene oxide has gained a lot of interest because of its large surfacearea and unique structure. Moreover, graphene oxide is an environmentally friendlymaterial. However, most of the reported studies did not use real wastewater samplesbut simulated ones prepared in labs. Therefore, the removal effects need to beexperimentally evidenced by using real wastewater samples. In this project, I studiedthe removal effects of pristine and modified graphene oxide using wastewatercollected at the wastewater treatment plant in Sundsvall (Fillan wastewater treatmentplant). Moreover, I have also studied the heavy metal removal effects of combinedcoagulation method and graphene oxide. Results have shown that graphene oxide hassimilar removal effects to the coagulation method, indicating the enormous potentialof graphene oxide in wastewater treatment. / <p>2021-09-19</p> Wastewater Heavy metals Graphene oxide Removal efficiency Environmental Sciences Miljövetenskap
50	Graphene-Based Materials in Metal-, Carbo- & Organocatalysis Gómez-Martínez, Melania 06 October 2017 (has links) Se ha estudiado la actividad catalítica de materiales derivados de grafeno como soporte de nanopartículas de paladio así como de complejos de paladio(II) en reacciones de acoplamiento carbono-carbono y carbono-heteroátomo. Así mismo, se ha llevado a cabo su actividad catalítica como carbocatalizador en diversas transformaciones orgánicas. Graphene Graphene Oxide Organocatalysis Palladium Carbocatalysis Química Orgánica

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