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81	Design and development of calcium titanate photocatalysts for endergonic reactions with water activation / 水の活性化を伴う吸エルゴン反応のためのチタン酸カルシウム光触媒の設計と開発 Anzai, Akihiko 23 March 2021 (has links) 京都大学 / 新制・課程博士 / 博士(人間・環境学) / 甲第23265号 / 人博第980号 / 新制\|\|人\|\|232(附属図書館) / 2020\|\|人博\|\|980(吉田南総合図書館) / 京都大学大学院人間・環境学研究科相関環境学専攻 / (主査)教授吉田寿雄, 教授田部勢津久, 教授中村敏浩 / 学位規則第4条第1項該当 / Doctor of Human and Environmental Studies / Kyoto University / DFAM Calcium titanate photocatalyst Photocatalytic Reduction of CO2 Silver cocatalyst Carbon monoxide Cation doping 361
82	Smart Photocatalytic Building Materials for Autogenous Improvement of Indoor Environment: Experimental, Physics-Based, and Data-Driven Modeling Approaches Jiang, Zhuoying 01 September 2021 (has links) No description available. Civil Engineering Materials Science Volatile organic compounds VOCs doped-TiO2 photocatalyst indoor air machine learning photodegradation kinetics
83	Studies of synthesis and photocatalytic properties of TiO[2] films with various morphologies / 多様な構造のTiO[2]膜の作製および光触媒特性に関する研究 Song, Duck-Hyun 24 September 2014 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第18612号 / エネ博第308号 / 新制\|\|エネ\|\|63(附属図書館) / 31512 / 京都大学大学院エネルギー科学研究科エネルギー応用科学専攻 / (主査)教授平藤哲司, 教授馬渕守, 教授土井俊哉 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM photocatalyst titania rod film silver core/titania shell nano-wire film three-dimensional titania building block titanium glycolate 501
84	Mono- and Bimetallic Polypyridyl Systems for Solar Energy Applications: Tuning and Identification of Excited States Through Ultrafast Spectroscopy Whittemore, Tyler 28 September 2018 (has links) No description available. Chemistry Inorganic Chemistry Physical Chemistry spectroscopy ruthenium dirhodium paddlewheels photochemistry photophysics chemistry ultrafast inorganic chemistry dyes photocatalyst photocatalysis catalysis
85	Solar concentration for the environment industry: photocatalytic materials and application technologies Fendrich, Murilo Alexandre 14 January 2021 (has links) This thesis presents the achievements pursued during the doctoral course. The work was carried out in the context of the project ERiCSol (Energia RInnovabile e Combustili SOLari), as part of the University of Trento strategic plan for the years 2017-2021. The project was conceived to establish an interdepartmental area to promote the challenge of developing scientific research and technological innovation to increase the competitiveness of Trento at national and international level in the areas of energy and environment. Among all the goals of the project, this work dedicates special attention to 1) development of novel materials for solar photocatalytic reactions and 2) use of renewable energy to push forward applications in water remediation. To accomplish these goals, the research brings a full collection of experimental activities regarding the employment of solar concentration for the environment industry and therefore this document is organized in 9 chapters. In chapter 1, it is presented the introduction outlining the overview of the environment industry, the employment of solar light as energy source and the general and specific objectives. Chapter 2 presents a literature review regarding the last 30 years of applications correlating the use of solar light towards wastewater purification. The chapter reviews the engineering features of solar collectors, photocatalyst materials employed and the panorama of the pollutants investigated up to the present date in solar photocatalysis, presenting comparisons between models and real wastewater approaches. Chapter 3 details the experimental techniques and characterizations employed to sustain the investigation proposed in the thesis. The first part of the chapter explains the features of parabolic dish solar concentrator designed and manufactured by the IdEA group at the physics department of the university of Trento. After, it is presented the pulsed laser deposition, a thin films fabrication technique employed to produce the photocatalysts used on water purification experiments. The second part of the chapter presents the description of the characterization techniques used to reveal the fabricated photocatalyst materials properties. Based on the review on the fundamentals of solar photocatalysis and the experimental techniques, chapters 4 and 5 present a discussion in the field of novel photocatalytic materials capable to operate under concentrated sunlight irradiation. Chapter 4 in special presents the investigation regarding the fabrication of tungsten trioxide (WO3) thin film coatings, bringing the novelty of using pulsed laser deposition as the fabrication method and the evaluation of this material in photocatalysis for the degradation of methylene blue dye model pollutant. Chapter 5 instead, presents the development on Zinc Oxide (ZnO) nanoparticles, bringing an innovative point of view on a “green-synthesis” approach and the material immobilization in film for heterogeneous photocatalysis routes. Chapters 6 and 7 discuss solar photocatalysis aiming to shift applications from model pollutants to real wastewater remediation conditions. Important comparisons are performed and discussed regarding the advantages and existing drawbacks. To fulfill this purpose, chapter 6 presents an application case of solar photocatalysis to the degradation of a surfactant-rich industrial wastewater whereas chapter 7 presents the approach focused on the remediation of organic lead contaminants present on a local water well site in the city of Trento. The last experimental approach of concentrated solar light is presented on chapter 8, dedicated to the application of concentrated sunlight towards waste biomass valorization. Conversely to the application on water previously described, this chapter presents the activity on designing, fabricating and coupling a hydrothermal reactor with concentrated sunlight using it as the driving force to promote degradation of grape seeds evolving into hydrochars with possible valorization of the carbonized material. Lastly, chapter 9 presents the conclusions and suggestions, this item expresses the final considerations on the results of the experimental investigations, advantages and limitations observed, and suggests possible actions for future works. Solar concentration Wastewater remediation Photocatalyst material Water pollutant Advanced oxidation process.
86	Modification of calcium titanate photocatalyst for carbon dioxide reduction with water / 水による二酸化炭素還元のためのチタン酸カルシウムの光触媒の修飾 Qiu, Hongxuan 25 March 2024 (has links) 京都大学 / 新制・課程博士 / 博士(人間・環境学) / 甲第25364号 / 人博第1106号 / 新制\|\|人\|\|259(附属図書館) / 京都大学大学院人間・環境学研究科相関環境学専攻 / (主査)教授吉田寿雄, 教授田部勢津久, 教授中村敏浩, 教授田中庸裕 / 学位規則第4条第1項該当 / Doctor of Human and Environmental Studies / Kyoto University / DFAM Modification of cocatalysts Photocatalytic CO2 reduction with water Electron-hole transfer enhancement Solar Energy Utilization Calcium titanate photocatalyst 361
87	Design and development of a new generation of UV-visible-light-driven nanosized codoped titanium dioxide photocatalysts and biocides/sporocides, and environmental applications Hamal, Dambar B. January 1900 (has links) Doctor of Philosophy / Department of Chemistry / Kenneth J. Klabunde / For solar environmental remediation, a new generation of nanosized (< 10 nm) titanium dioxide photocatalysts codoped with metals and nonmetals, or metals only were prepared by the xero-gel and aero-gel methods. For silver or cobalt-based xero-gel titanium dioxide photocatalysts, photoactivities tests revealed that codoping of titanium dioxide with a metal (1% Ag or 2% Co) and nonmetals (carbon and sulfur) is necessary to achieve high-activities for acetaldehyde degradation under visible light (wavelength > 420 nm). It was concluded that high visible-light-activities for acetaldehyde degradation over codoped titanium dioxide were attributed to an interplay of anatase crystallinity, high-surface area, reduced band-gap (< 3.0 eV), uniform dispersion of doped metal ions, and suppressed recombination rate of photogenerated electron-hole pairs. Moreover, the nature and amount of codoped metals play a significant role in visible-light-induced photocatalysis. Metals (Al, Ga, and In) doped/codoped titanium dioxide photocatalysts were prepared by the aero-gel method. The photocatalytic studies showed that activities of metal doped/codoped photocatalysts under UV light (wavelength < 400 nm) were found to be dependent on pollutants. Indium demonstrated beneficial effects in both textural and photocatalytic properties. Gallium and indium codoped titanium dioxide photocatalysts displayed even better performance in the CO oxidation reaction under UV light. Notably, titanium dioxide codoped with Ga, In, and Pt, exhibited unique photoactivities for the CO oxidation under both UV and visible light irradiation, indicating that this system could have promise for the water-gas shift reaction for hydrogen production. Silver-based nanostructured titanium dioxide samples were developed for killing human pathogens (Escherichia coli cells and Bacillus subtilis spores). Biocidal tests revealed that silver, carbon, and sulfur codoped titanium dioxide nanoparticles (< 10 nm) possess very strong antimicrobial actions on both E. coli (logarithmic kill > 8) and B. subtilis spores (logarithmic kill > 5) for 30 minute exposures in dark conditions compared with Degussa P25. It was believed that the carbon and sulfur codoped titanium dioxide support and Ag species acted synergistically during deactivation of both E. coli and B. subtilis spores. Thus, titanium dioxide codoped with silver, carbon, sulfur can serve as a multifunctional generic biocide and a visible- light-active photocatalyst. Nanosized Titanium Dioxide Visible-light-active photocatalyst Biocide-Sporocide Codoped Titania Photooxidation Environmental applications Chemistry, Inorganic (0488) Engineering, Materials Science (0794) Environmental Sciences (0768)
88	Síntese de estruturas 3D de nanotubos de carbono verticalmente alinhados, dopados e não-dopados, decorados com nanopartículas de óxido de titânio, sua caracterização microestrutural e de propriedades fotocatalíticas e elétricas Acauan, Luiz Henrique January 2015 (has links) Neste trabalho foi desenvolvido um procedimento experimental para a fabricação de estruturas 3D de nanotubos de carbono crescidos sobre substrato de cobre e decorados com partículas de óxido de titânio. Foram relacionados os três tipos diferentes de NTCs nesta estrutura (simples, dopados com nitrogênio e tratados com plasma) com a deposição do TiO2 por ALD. Foram igualmente propostas três aplicações para esta estrutura. A síntese dos NTCs verticalmente orientados, dopados e não dopados, foi otimizada dentre alguns parâmetros de síntese como temperatura, agente oxidante e principalmente, o filme catalisador. A introdução de defeitos nos NTCP através do tratamento a plasma oxidativo foi avaliada frente a variáveis como pressão, potência e tempo de exposição. A relação entre os defeitos destes três tipos de NTCs e a deposição de TiO2 por ALD foi avaliada por microscopia eletrônica de transmissão, Raman, XPS e TGA. O procedimento experimental para confecção da estrutura 3D foi desenvolvido etapa por etapa via diversas técnicas experimentais, desde caracterização química, imagem, até testes empíricos. Na estrutura final, foram avaliadas as propriedades fotocatalíticas pela decomposição de corante orgânico em meio aquoso, propriedades capacitivas por voltametria cíclica e propriedades de emissão por campo através de curvas de campo elétrico por corrente de emissão e diagramas F-N. Foram obtidas florestas de NTCs de boa qualidade com até 0.5mm de altura, de diâmetros e número de paredes regulares. Nestes foi possível introduzir defeitos de maneira controlável, mantendo o arranjo da floresta. As florestas de NTCNx alcançam uma altura de até 0,3mm com concentração de nitrogênio de 2% tendo os nanotubos uma estrutura típica “bamboo-like”. Os resultados mostram a relação entre o tipo de defeito e a deposição de TiO2 por ALD, obtendo-se partículas cristalinas para os NTCP e NTCNx, sendo neste ultimo as partículas homogeneamente distribuídas e com tamanho uniforme, enquanto nos NTCOx forma-se uma densa camada de TiO2 composta por grandes grãos monocristalinos A partir de processo como tratamentos térmicos e transferência dos NTC de substrato foi possível obter uma estrutura 3D composta de uma camada carbono grafítico e NTC-VAs sobre um substrato de cobre, sem alterar o arranjo inicial das florestas. As amostras mostraram efeito de emissão de elétrons por campo elétrico, porém estas requerem uma análise mais quantitativa. Os ensaios de fotocatálise mostraram que a imobilização do TiO2 em um suporte denso inviabiliza a degradação do corante em meio aquoso. Os NTCNx apresentaram maior capacitância que as mostras de NTCP, e o TiO2 foi aparentemente ineficaz para a melhoria desta propriedade. / In this work, we propose an experimental procedure for fabrication of 3D carbon nanotubes structures anchored with titanium oxide particles, on a copper substrate. We correlate three different types of CNTs from this structure (pristine, doped with nitrogen and treated with plasma) with the deposition of TiO2 by ALD. It was yet suggested, three applications for this structure. The synthesis of vertically aligned CNTs, doped and undoped, was optimized among several synthesis parameters such as temperature, oxidizing agent and specially, the catalyst film. The introduction of defects in NTCP by oxidative plasma treatment was evaluated against variables such as pressure, power and exposure time. The association between the defects from these three types of CNTs and the deposition of TiO2 by ALD was assessed by transmission microscopy, Raman, XPS and TGA. The experimental procedure for assembling the 3D structure had been studied step by step by various techniques, from chemical and imaging, up to empirical testing. In the final structure, the photocatalytic properties were evaluated by the organic dye decomposition in an aqueous medium, capacitive properties by cyclic voltammetry and field emission properties through electric field versus emission current curves and F-N diagram. Was obtained high quality NTCs with a height up to 0.5mm with regular diameters and number of walls. On these, it was introduced, in a controllable way, a high amount of defects without jeopardizing the forest structure. The NTCNx forest reach a 0,3nm height with a 2% nitrogen concentration in its typical structure “bamboo-like”. The results show the relation between the type of defect and the deposition of TiO2 by ALD, forming crystalline particles over the NTCP and NTCNx, in this last evenly distributed with uniform size, while on the NTCOx is is formed a dense TiO2 layer shaped by large monocrystalline grains. By process such as heat treatments and CNT transferring was achieved a 3d structure composed by a graphitic carbon layer and VACNTs over a cupper substrate, without disturb the forest assembly. The samples showed electron field emission effect, but its assessment for quantitative analysis was limited to technical issues. The photocatalysis tests showed that immobilization of TiO2 on a dense support prevents the dye degradation in an aqueous medium. The NTCNx shown higher capacitance than NTCP, and the TiO2 was apparently ineffective for improvement of this property. Nanotubos de carbono Nanoparticulas Óxido de titânio Fotocatálise Carbon nanotubes Nitrogen doped carbon nanotubes Plasma-treated carbon nanotubes TiO2 ALD 3D carbon structures Photocatalyst Supercapacitance Field emission
89	Nanoparticules à base d’oxyde de titane pour la photocatalyse / Titanium based oxides nanoparticles for photocatalysis Jimenez Romero, Alex Manuel 05 March 2013 (has links) Des nanoparticules à base d’oxyde de titane ont été synthétisées par pyrolyse laser en vue de leur application dans le domaine de la photocatalyse. Le travail montre la souplesse de la méthode pour la synthèse de TiO2 et M-TiO2 (M= Pd, Fe, Cu, Si, N) à partir de tetraisopropoxyde de titane. Des sels organiques des métaux, de SiH4 et d’NH3 ont été utilisés pour introduire des atomes de Fe, Cu, Pd, Si et N dans des nanoparticules de TiO2. Les nanoparticules ont été analysées par microscopie électronique de transmission (MET), diffraction de rayons X (DRX), surface spécifique (SBET), spectroscopie des photoélectrons X (XPS), spectrométrie d’émission à torche plasma (ICP/OES). Leurs propriétés optiques ont été évaluées par spectroscopie de réflexion diffuse (DRS). L’activité photocatalytique des nanoparticules synthétisées a été évaluée dans la dégradation du bleu de méthylène, de l’acide formique et du phénol, sous d’irradiation UV et/ou UV-Visible. Les résultats ont été comparés à ceux obtenus dans les mêmes conditions avec le produit commercial Degussa P25 de chez Evonik.Les analyses montrent que les échantillons sont composés de nanoparticules sphériques avec une distribution de taille comprise entre 5 et 20 nm, la phase cristallographique majoritaire est le TiO2 anatase. Les surfaces développées en analyse BET sont importantes, autour de 80 m2/g (170 pour N-TiO2), comparées au produit commercial Degussa P25. Les analyses chimiques montrent que les atomes de Fe, Cu, Pd, Si et N sont efficacement introduits dans les nanoparticules de TiO2 avec des rendements MPoudre/MPrécurseur au moins égaux à 48%.Les échantillons de TiO2, Pd-TiO2 et Cu-TiO2 montrent une meilleure activité que TiO2 Degussa P25 vis-à-vis de la décomposition d’acide formique sous irradiation UV-Vis tandis que Fe-TiO2, Si-TiO2 et N-TiO2 sont moins actifs. L’effet de la concentration et de l’état d’oxydation du Pd dans le TiO2 a alors été étudié plus spécifiquement. L’addition de Pd sous la forme PdO diminue l’activité vis-à-vis de la décomposition de l’acide formique et du bleu de méthylène. Par contre l’addition de Pd sous la forme métallique améliore l’activité vis-à-vis de la dégradation du bleu de méthylène, d’acide formique et du phénol. Cette activité est toujours aussi importante après quatre cycles de photocatalyse.Nous avons également évalué l’activité des oxynitrures de titane et de N-TiO2 vis-à-vis de la dégradation de l’acide formique et de la décoloration du bleu de méthylène sous irradiation visible. Les oxynitrures présentent des activités faibles, qui semblent être améliorées par l’addition de palladium. L’échantillon N-TiO2 montre quant à lui des excellentes propriétés photocatalytiques vis-à-vis de la dégradation de l’acide formique sous irradiation visible tout en gardant une très bonne efficacité sous l’UV. / Titanium based oxides nanoparticles were synthesized by laser pyrolysis and were tested as possible as photocatalysts. Using the laser pyrolysis method, this work shows that TiO2 and M-TiO2 (M = Pd, Fe, Cu, Si, N) can be easily synthesized in one step from titanium tetra isopropoxideprecursor mixed with organic salts of metals, SiH4 or NH3 to introduce atoms of Fe, Cu, Pd, Si and N in TiO2 nanoparticles. Nanoparticles were characterized by transmission electron microscopy (TEM), X-ray diffraction (XRD), Brunauer-Emmett-Teller specific surface (SBET), X-photoelectron spectroscopy (XPS), and inductively coupled plasma spectroscopy (ICP/EOS). Their optical properties were measured by diffuse reflection spectroscopy (DRX). Photocatalytic activity of nanoparticles was evaluated using the degradation of methylene blue, formic acid and phenol tests under UV (360 nm) and/or UV-Visible(290-780nm) or pure visible radiation (455 nm). Results were compared to those of TiO2 Degussa P25 (from Evonik) obtained under same conditions.The nanoparticles are of spherical shape with a size distribution from 5 to 10 nanometers, there are mostly in anatase crystallographic phase. The specific surfaces area is always around 80 m2/g (170 m2/g for N-TiO2), indicating smaller size than TiO2 Degussa P25. Chemical analysis indicate that Fe, Cu, Pd, Si and N atoms are efficiently introduced into TiO2 powders. The mass ration MPowder/MPrecursor yield is always higher than 48%.Using the formic acid degradation test, TiO2, Pd-TiO2 and Cu-TiO2 were more active than TiO2 Degussa P25 test under UV-Vis radiation while Fe-TiO2, Si-TiO2 and N-TiO2 were less actives. Therefore, the influence of Pd amount/oxidation state upon the photocatalytic properties of Pd-TiO2 nanoparticles was studied in more details. Pd-TiO2 activity to degrade methylene blue, formic acid and phenol was improved in presence of metallic palladium. This activity is still important after 4 tests cycles.The activity of Titanium Oxynitride (exhibiting large shift of the optical gap towards the visible region) and N-doped TiO2 nanoparticles was also studied in formic acid and methylene blue degradation test under visible radiation. Oxynitrides exhibit low activity, which appears to be improved by the addition of palladium. This low activity could be related to the presence of an amorphous phase in the sample. N-TiO2 samples were active in formic acid degradation under visible radiation while keeping a very good efficiency in the UV. Nanoparticules Laser pyrolyse TiO2, Pd-TiO2, oxynitrures de titane Photocatalyse Acide formique Phénol Bleu de méthylène Nanoparticles Laser pyrolysis TiO2, Pd-TiO2 Titanium oxynitrides Photocatalyst Formic acid Phenol Methylene blue
90	Photocatalytic behaviour of nano sized titanium dioxide (TiO2) blended in poly (lactic acid) (PLA) via melt blending method : focus on textile applications CHENGJIAO, ZHANG January 2013 (has links) During this project, photocatalytic material, nano sized titanium dioxide, was introduced into poly (lactic acid) to produce functional surface capable of self-cleaning property. Samples containing 0%, 5%, 10%, 15% and 20% titanium dioxide were prepared and etched with proteinase K to expose the nano particles on the surface. It was shown that the nano titanium dioxide could dispersed in the polymer matrix pretty well, it was also found that the nano particles affected the thermal and mechanical properties of the polymer matrix differently , due to difference in concentrations of nano filler. The self-cleaning property was evaluated by decolouration of stains caused by coffee and red wine, also by detecting degradation of methylene blue via a UV-vis spectrophotometer. By measuring changes in absorbance of light at 664nm wavelength after a maximum of 24h UV irradiation, it was possible to measure the degradation property of the samples. / Program: Masterutbildning i textilteknik Titanium dioxide (P25 poly(lactic acid)(PLA), self-cleaning surface photocatalyst photocaltalytic activity enzymatic degradation methylene blue photo-degradation Engineering and Technology Teknik och teknologier

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