Global ETD Search

641	電気泳動法による色素増感型太陽電池の高光電変換効率化に関する研究 / デンキエイドウホウニヨルシキソゾウカンガタタイヨウデンチノコウコウデンヘンカンコウリツカニカンスルケンキュウ川上亮, Ryo Kawakami 22 March 2015 (has links) 本論文は，色素増感型太陽電池(DSSC)に一般的に用いられる酸化チタン(TiO2)粒子(P25)および光電変換効率が比較的に高いとされるTiO2ナノ粒子について，薄膜作製および増感色素の吸着に電気泳動法を使用することを提案し，DSSCの光電変換効率の向上を目指して研究を行い，得られた成果を生かすことでDSSCの光電変換効率のさらなる向上，さらには量産性の大幅な向上の可能性を示したものである。 / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University 色素増感太陽電池酸化チタン薄膜電気泳動法 dye-sensitized solar cell titanium dioxide thin film electrophoresis
642	Synthesis and physicochemical evaluation of metal oxide powders which reveal antibacterial activity under dark conditions / 暗所抗菌性を有する金属酸化物の合成と物理化学的特性評価 / アンショコウキンセイオユウスルキンゾクサンカブツノゴウセイトブツリカガクテキトクセイヒョウカ Phuong Thi Minh Nguyen 22 March 2020 (has links) 濃度3Mの硝酸亜鉛水溶液中170°Cで7 h水熱処理し，ついで大気中600℃で再酸化処理して合成した酸化亜鉛ZnOは持続的な暗所抗菌性を示す．このZnOについて物理化学な物性を詳細に検討した．また，カリウムKとりんPを1:3の原子比率で添加固溶させたアナターゼ型酸化チタンTiO2は暗所でも抗菌性を示すことを新たに見出した．その抗菌性発現のメカニズムについて検討した結果を報告する． / Both ZnO and TiO2 have high potential as antibacterial agents which are able to apply in various fields. Although there are already many studies about these materials focusing on their antibacterial activity, they are still getting more attention from researchers due to their unclear mechanism under dark. There have been very few reports mentioning clearly about this. Besides, the effects of the preparation methods and their physicochemical properties to the antibacterial property of ZnO, TiO2 and doped TiO2 under dark also have not been well-characterized. In the present study, synthesis and physicochemical evaluation of metal oxides which reveal antibacterial activity even in the dark conditions have been performed. / 博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University 酸化亜鉛酸化チタン暗所抗菌性 Zinc oxide Titanium dioxide
643	Spectroscopic Characterization of Metal Oxide Nanofibers Bender, Edward Thomas 18 May 2006 (has links) No description available. nanofibers electrospinning X-ray photoelectron spectroscopy XPS Fourier transform infrared spectroscopy FTIR secondary Ion Mass Spectroscopy SIMS infrared emission IRES photoacoustics titanium dioxide titania aluminum oxide alumina
644	[pt] ESTUDO DA COALESCÊNCIA DE GOTAS DE ÓLEO EM ÁGUA USANDO NANOPARTÍCULAS / [en] STUDY OF COALESCENCE OF OIL DROPLETS IN WATER USING NANOPARTICLES GLAUCIA TEIXEIRA DA SILVA 30 June 2020 (has links) [pt] Muitas indústrias, como as de petróleo, cosméticos e farmacêuticos, buscam estabilizar emulsões de forma efetiva e com menor custo. O uso de partículas sólidas como agentes emulsificantes (emulsões Pickering) tem apresentado grandes benefícios, como custo e estabilidade das emulsões, quando comparados aos surfactantes, que são utilizados na emulsão clássica. A eficácia de uma determinada partícula na estabilização de uma emulsão depende das suas propriedades e da sua interação com as fases oleosa e aquosa da emulsão. Essas partículas sólidas adsorvem-se na interface óleo-água criando uma fina camada entre as fases, evitando a coalescência das gotas. Uma forma de estudar a estabilidade de emulsões Pickering é analisar o experimento de coalescência de duas interfaces óleo-água que são forçadas uma contra a outra. A metodologia deste trabalho baseou-se em medições do tempo de coalescência de uma gota de óleo, presente em uma dispersão aquosa de nanopartículas, quando a mesma é forçada contra uma interface óleoágua. Para a correta visualização e registro do momento da coalescência da gota utilizou-se uma câmera de alta velocidade (Photron FastCam SA3). As nanopartículas utilizadas foram: Laponita RD, dióxido de titânio HAc e Aerosil R972. Observou-se tempos de coalescência maiores para testes com dispersões aquosas de Laponita RD 1,0 porcento (m/m) e de Aerosil R972 0,0024 porcento (m/m) do que para testes com água pura (Milli-Q). / [en] Several industries, such as oil and gas, cosmetics, and pharmaceutical, seek to stabilize emulsions more effectively and at a lower cost. As compared to surfactants, which are used in classic emulsions, the use of solid particles as emulsifying agents (Pickering emulsions) has presented great benefits, including lower costs and better emulsion stability. A particle s effectiveness on stabilizing an emulsion is related to its properties, as well as its interaction with the oil and water phases of the emulsion. These solid particles adsorb at the oil-water interface, creating a thin layer between the phases, and thus avoiding the coalescence of the droplets. One method to study the stability of Pickering emulsions is to analyze the coalescence experiment of two oil-water interfaces that are forced against each other. The methodology of this work was based on measurements of the coalescence time of an oil droplet in an aqueous dispersion of nanoparticles, when it is forced against an oil-water interface. A high speed camera (Photron FastCam SA3) was used for the proper visualization and recording of the moment of drop coalescence. The three types of nanoparticles used were: Laponite RD, titanium dioxide HAc, and Aerosil R972. Longer coalescence times were observed for tests with aqueous dispersions of Laponite RD 1.0 percent (w/w) and Aerosil R972 0.0024 percent (w/w) versus tests with plain water (Milli-Q). [pt] DIOXIDO DE TITANIO [pt] INTERFACE OLEO AGUA [pt] LAPONITA [pt] SILICA [pt] EMULSOES PICKERING [pt] COALESCENCIA [en] TITANIUM DIOXIDE [en] INTERFACE OIL WATER [en] LAPONITE [en] SILICA [en] PICKERING EMULSIONS [en] COALESCENCE
645	[en] LOW-TEMPERATURE SINTERING OF TITANIA USED IN PHOTOCATALYTIC REACTIONS / [pt] SINTERIZAÇÃO A BAIXAS TEMPERATURAS DA TITÂNIA USADA EM REAÇÕES FOTOCATALÍTICAS ANNA LUISA WERNECK RUOTOLO MIGUEL 16 November 2021 (has links) [pt] A busca pela diminuição da dependência de combustíveis fósseis faz com que a ciência avance, diariamente, na utilização de combustíveis ecológicos, como o H2. Uma das formas de sua obtenção é através da fotocatálise. Esse processo consiste em uma reação catalítica com o uso de energia, na forma de luz. A fotólise da água é amplamente utilizada, principalmente com luz solar como fonte luminosa, que é abundante e reduz os custos de sua produção. O desempenho desta reação depende da posição das bandas de condução (BC) e valência (BV) do fotocatalisador. O TiO2 é utilizado como fotocatalisador em diversas reações, inclusive para a produção de H2. Os fotocatalisadores utilizados na forma de pós nanométricos apresentam dificuldade de separação após a reação. A transformação do pó em um material compacto é uma alternativa para retirá-lo do meio reacional evitando perdas e custos com separação. Desse modo, a compactação do pó é uma alternativa para facilitar sua reciclagem. O principal método de sua produção é pelo processo de sinterização, que envolve temperaturas elevadas (geralmente, 75 por cento do ponto de fusão do material) e longo tempo, podendo durar até dias. Para diminuir os gastos energéticos, o processo de sinterização a frio é uma opção, que consiste na densificação do material com uso de pressão e um solvente (aquoso ou não) e, temperaturas de sinterização de até 500 Graus C. O objetivo do estudo consistiu na produção de pastilhas de TiO2, comercial, e P25, através de uma variação do método de sinterização a frio, onde aplicou-se a pressão no pó, junto com o solvente, antes de seu tratamento térmico. As pastilhas produzidas foram caracterizadas pelas técnicas de TGA/DSC, XRD, MEV, CV, e DRS. / [en] The quest to reduce dependence on fossil fuels makes science advance, daily, in the use of ecological fuels, such as H2. One of the ways to obtain it is through photocatalysis. This process consists on a catalytic reaction using energy, in the form of light. Water photolysis is widely used, mainly with sunlight as a light source, which is abundant and reduces production costs. The performance of this reaction depends on the position of the conduction (CB) and valence (VB) bands of the photocatalyst. TiO2 is used as a photocatalyst in several reactions, including the production of H2. Photocatalysts used in the form of nanometric powders have difficulty in separating after the reaction. The transformation of the powder into a compact material is an alternative to remove it from the reaction medium, avoiding losses and costs with separation. Thus, the compaction of the powder is an alternative to facilitate its recycling. The main method of its production is through the sintering process, which involves high temperatures (generally 75 percent of the material s melting point) and a long time, which can last up to days. To reduce energy costs, the cold sintering process is an option, which consists of densifying the material using pressure and a solvent (aqueous or not) and sintering temperatures of up to 500 C degrees. The aim of the study was the production of commercial TiO2 and P25 pellets, through a variant of the cold sintering method, where pressure was applied to the powder, with the proper solvent, before the heat treatment. The pellets produced were characterized by the techniques of TGA/DSC, XRD, SEM, CV, and DRS. [pt] DIOXIDO DE TITANIO [pt] P25 [pt] ANATASIO [pt] SINTERIZACAO A FRIO [pt] VOLTAMETRIA CICLICA [en] TITANIUM DIOXIDE [en] P25 [en] ANATASE [en] COLD SINTERING PROCESS [en] CYCLIC VOLTAMMETRY
646	Photocatalytic Degradation of Organic Substances in Salt Water / Fotokatalytisk nedbrytning av organiska ämnen i saltvatten Carlsson, Celice, Wiklund, Love, Svensson, Emilie, Fégeant, Benjamin January 2021 (has links) The purpose of this research was to investigate the kinetics and mechanisms of the photocatalytic degradation of organic substances in the presence of anions (bromide and chloride), using titanium dioxide as a photocatalyst. Tris(hydroxymethyl)aminomethane (Tris) and methanol were the organic substances used as probes. Photocatalytic degradation of the probes produces formaldehyde through reaction with hydroxyl radicals at the surface of the photocatalyst. The product was quantified using a modified Hantzsch reaction and UV-Vis spectroscopy at the fixed wavelength 368 nm. It was found that having bromide present in the reaction mixture resulted in an increase in the rate of formation of formaldehyde from Tris, while it resulted in a decrease from methanol. Bromide on the surface of the photocatalyst reacts with the hydroxyl radicals to form reactive halogen species (RHS). This study proposes that the RHS Br2•- oxidises the probe into a cation radical, which initialises the probe degradation and the subsequent formation of formaldehyde. Conversion from hydroxyl radicals to RHS leads to a greater selectivity in formaldehyde production. Increased selectivity of attack towards electron-rich centres can explain the observed results with the different probes in this study. A linear combination expression of the total production of formaldehyde was developed, through which the X-factor, a ratio of the production of formaldehyde by RHS relative to the production of formaldehyde by hydroxyl radicals, was calculated. However, no realistic values were obtained when calculating the X-factor for different anion concentrations, thus indicating that factors other than competition kinetics affect the degradation. No conclusions could be drawn regarding the effect of chloride on the formation of formaldehyde from Tris and methanol, as the results were ambiguous. / Syftet med denna studie var att undersöka mekanismer och kinetik bakom fotokatalytisk nedbrytning av organiska molekyler i närvaro av anjoner (bromid och klorid), där titandioxid användes som fotokatalysator. Tris(hydroxymetyl)aminometan (Tris) och metanol var de organiska substanserna som studerades. Den fotokatalytiska nedbrytningen av proberna resulterar i formaldehyd via reaktion med hydroxylradikaler på fotokatalysatorns yta. Produkten kan sedan kvantifieras genom en modifierad version av Hantzsch-reaktionen följt av UV-Vis spektroskopi vid en fixerad våglängd på 368 nm. Studien kom fram till att närvaron av bromid i reaktionslösningen resulterade i en ökad produktionshastighet av formaldehyd från Tris, medan det resulterade i en minskning från metanol. Bromid på ytan av fotokatalysatorn reagerar med hydroxylradikaler och bildar reaktiva halogena molekyler (RHS). Denna studie föreslår att RHS:en Br2•- oxiderar proben till en radikalkatjon, som initierar nedbrytningen av proben och efterföljande bildning av formaldehyd. Omvandling från hydroxylradikaler till RHS leder till högre selektivitet av bildning av formaldehyd. Ökad selektivitet av attacker mot elektronrika center kan förklara de observerade resultaten med de olika proberna i denna studie. Ett linjärkombinationsuttryck av den totala produktionen av formaldehyd utvecklades, från vilket X-faktorn, ett förhållande av produktionen av formaldehyd via RHS relativt till produktionen av formaldehyd via hydroxylradikaler, kunde beräknas. Inga realistiska värden erhölls dock vid beräkningen av X-faktorn för olika anjonskoncentrationer, vilket indikerar att andra faktorer än konkurrenskinetik påverkar nedbrytningen. Inga slutsatser kunde dras gällande klorids effekt på bildningen av formaldehyd från Tris och metanol, då resultaten var tvetydiga. Photocatalytic degradation titanium dioxide reactive halogen species Tris(hydroxymethyl)aminomethane methanol competition kinetics Fotokatalytisk nedbrytning titandioxid reaktiva halogen molekyler Tris(hydroxymetyl)aminometan metanol konkurrenskinetik Physical Chemistry Fysikalisk kemi
647	Bursting the Bubble: Membraneless Electrolyzers and High-Surface Oxide Coated Electrodes for Brine Management Fraga Alvarez, Daniela Valeska January 2023 (has links) High levels of water stress and increased demand for potable water generated via desalination pose significant challenges for sustainable waste brine management in arid regions. Electrochemical techniques, like brine electrolysis, offer an approach for treating brine, preventing environmentally harmful disposal, and facilitating the recycling of valuable ions found in brine. As the large concentration of ions can precipitate and degrade conventional electrolyzer components, membraneless electrolyzers, which lack membranes, can be an alternative for direct brine electrolysis. The absence of membranes enables operation in the presence of impurities and a wide range of pH environments. However, membraneless electrolyzers suffer from a trade-off between current density and current utilization that stems from undesired back-reactions that arise from the crossover of gaseous and aqueous products between the anode and cathode. In this dissertation work, a combination of in situ high-speed video, colorimetric pH imaging, modeling, and electroanalytical methods were used to evaluate how the performance of a porous flow-through cathode is affected by operating current density, electrolyte flow rate, and choice of catalyst placement on a porous support. It was found that catalyst placement is a key knob to control the location of product generation and thereby minimize product crossover and maximize pH differential. Placing the catalyst on the outer surface of the cathode resulted in an average increase of 51% in current utilization, a metric for measuring crossover, compared to the opposite configuration. This finding is explained by the ability of the porous electrode support to serve as a barrier to suppress crossover for the outward-facing catalyst configuration. In addition, the outward-facing catalyst configuration leads to more stable operation while incurring minor increases (90-170 mV) in overpotentials. For both catalyst configurations, it was also shown that the Damköhler number (𝐷𝑎) is a practical descriptor for predicting operating conditions that maximize the concentration of OH⁻ in the cathode effluent stream. Furthermore, this dissertation evaluated the performance of a platinized cathode within a membraneless electrolyzer in the presence of Mg²⁺ impurities. In a 3-hour stability test at 50 mA cm⁻² during brine electrolysis, electrolytes with Mg²+ concentration below 5 mM showed a negligible influence on cathode performance. Electrolytes with Mg²⁺ concentration below 1.2 mM at similar operating conditions exhibited improved cathode performance compared to Mg-free brine. All learnings during this study were captured in a mathematical model that predicts the tolerance threshold at which the cathode would cease to operate due to accumulations of Mg(OH)₂ deposits at different current densities and superficial velocities. Overall, these studies demonstrated the potential of membraneless electrolyzers as an emerging technology for treating brine and converting it into high-value products. Finally, applying an oxide overlayer to planar electrodes has been demonstrated to improve their stability, activity, and/or selectivity. This is relevant for direct brine electrolysis, as brine contains many impurities that can compromise the integrity of electrodes and promote undesirable reactions, generating toxic products like chlorine gas. However, given that high-surface electrodes are required for industrial applications, it is necessary to develop a method to encapsulate high-surface-area electrodes. Applying nanoscopic oxide encapsulation layers to high-surface-area electrodes such as nanoparticle-supported porous electrodes is not an easy task. This dissertation work demonstrated that the recently developed condensed layer deposition (CLD) method can be used for depositing nanoscopic (sub-10 nm thick) titanium oxide (TiO₂) overlayers onto high surface area platinized carbon foam electrodes. Characterization of the overlayers by transmission electron microscopy (TEM) and electron energy loss spectroscopy (EELS) showed they are amorphous, while X-ray photoelectron microscopy confirmed that they exhibit TiO₂ stoichiometry. Electrodes were also characterized by hydrogen underpotential deposition (Hupd) and carbon monoxide (CO) stripping, demonstrating that the Pt electrocatalysts remain electrochemically active after encapsulation. Furthermore, copper underpotential deposition (Cuupd) measurements for bare Pt and TiO₂-encapsulated Pt electrocatalysts revealed that the TiO₂ overlayer effectively prevented Cu₂+ from reaching the buried, allowing this method to determine the coverage of the TiOx coating. In summary, this portion of the dissertation demonstrated that CLD is a promising method for applying nanoscopic overlayers on high-surface electrodes. Engineering Water resources development--Management Saline water conversion Electrolytic cells Electrodes, Oxide Electrodes, Porous Magnesium Titanium dioxide Copper High-speed video recording
648	Novel Preparation of Nanostructured Titanium Dioxide Photocatalytic Particles, Films, Membranes, and Devices for Environmental Applications Choi, Hyeok 02 July 2007 (has links) No description available. Engineering, Environmental Titanium Dioxide Photocatalysis Advanced Oxidation Technologies Environmental Application Nanoscience and Nanotechnology Green Engineering and Sustainability Nanostructured and Functional Materials
649	Toxicity of Food-Relevant Nanoparticles in Intestinal Epithelial Models McCracken, Christie Joy 01 October 2015 (has links) No description available. Biomedical Research Nanotechnology Toxicology
650	Die Rolle des Sauerstoffanteils in Titandioxid bei Tantal-Dotierung zur Verwendung als transparentes leitfähiges Oxid Neubert, Marcel 29 February 2016 (has links) (PDF) Im Fokus der vorliegenden Arbeit lag die Untersuchung polykristalliner TiO2:Ta-Schichten, hergestellt mittels Gleichstrom-Magnetron-Sputtern durch Verwendung reduzierter keramischer Targets und anschließender thermischer Nachbehandlung im Vakuum der zunächst nichtleitfähigen amorphen Precursorschichten. Es wurden die physikalischen Zusammenhänge, welche die strukturellen, elektrischen und optischen Eigenschaften der kristallinen TiO2:Ta-Schichten beeinflussen analysiert und dabei eine empfindliche Abhängigkeit vom Sauerstofffluss während der Abscheidung festgestellt. Es zeigte sich, dass die Verringerung der kinetischen Energie der Plasmateilchen beim Magnetron-Sputtern durch die Erhöhung des Gesamtdruckes vorteilhaft ist, um das Wachstum des gegenüber Rutil besser leitfähigen Anatas in Verbindung mit dem für niedrige Widerstände notwendigen Sauerstoffdefizit zu realisieren. Bei einem Gesamtdruck von 2 Pa abgeschiedene polykristalline TiO2:Ta-Schichten haben einen spezifischen Widerstand von 1,5·10-3 Ωcm, eine hohe Ladungsträgermobilität (≈8 cm2V-1s-1) und einen geringen Extinktionskoeffizienten von 0,006. Die Abhängigkeit des elektrischen Widerstandes vom Sauerstoffdefizit in der TiO2:Ta-Schicht wurde unter dem Gesichtspunkt der Ladungsträgeraktivierung sowie der Bildung von Ti-Fehlstellen diskutiert, welche vermutlich zur Kompensation und Lokalisierung von freien Elektronen beitragen. Darüber hinaus wurde zur effizienteren Gestaltung der thermischen Nachbehandlung die konventionelle Vakuumtemperung erstmalig erfolgreich durch die Blitzlampentemperung ersetzt. / The work is focused on understanding the physical processes responsible for the modification of the structural, electrical and optical properties of polycrystalline TiO2:Ta films formed by vacuum annealing of initially not conductive amorphous films deposited by direct current magnetron sputtering. It is shown that the oxygen deficiency of amorphous and annealed TiO2:Ta films, respectively, is critical to achieve low resistivity and high optical transmittance of the crystalline films. Increasing the total pressure during magnetron sputter deposition is shown to be beneficial to achieve the desired oxygen deficient anatase growth, which is discussed in terms of energetic particle bombardment. Polycrystalline anatase TiO2:Ta films of low electrical resistivity (1,5·10-3 Ωcm), high free electron mobility (≈8 cm2V-1s-1), and low extinction (0,006) are obtained in this way at a total pressure of 2 Pa. The dependence of the polycrystalline film electrical properties on the oxygen content is discussed in terms of Ta dopant electrical activation as well as transport limiting processes taking into account the formation of Ti-vacancies. In addition, the conventional vacuum annealing has been successfully substituted by the flash lamp annealing in the millisecond range. Titandioxid Tantal Halbleiter transparente leitfähige Oxide Magnetron Sputtern Ultra-Kurzzeittemperung elektrische Aktivierung Kristallisation titanium dioxide tantalum semiconductor transparent conductive oxide magnetron sputtering very-rapid annealing electrical activation crystallization ddc:530 Titandioxid Halbleiter Oxide Sputtern Kristallisation

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