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481	Fotocatálise heterogênea com Ti'O IND.2' aplicada ao tratamento de esgoto sanitário secundário / Ti'O IND.2' heterogeneous photocatalysis in secondary wastewater treatment Ferreira, Ivete Vasconcelos Lopes 16 December 2005 (has links) Este trabalho teve como objetivo estudar a fotocatálise heterogênea com Ti'O IND.2' no tratamento de esgoto sanitário secundário, visando a oxidação da matéria orgânica e desinfecção. A luz solar foi utilizada como fonte de radiação. O reator fotocatalítico consistiu de placa de vidro (aproxidamente 0,48 'M POT.2') sobre a qual foi fixado o catalisador (10 g/'M POT.2'). Foi avaliada a influência de parâmetros operacionais (vazão e ângulo de inclinação do fotorreator) na eficiência do processo. As vazões de estudo foram 15; 22,5 e 30 L/h, e os ângulos de inclinação em relação à horizontal foram 2, 12 e 22 graus. Os experimentos foram realizados com dois tipos de efluentes. O primeiro (efluente 1) foi de reator anaeróbio compartimentado tratando esgoto doméstico e o segundo (efluente 2) de reator anaeróbio/aeróbio de leito expandido com meio suporte constituído de carvão ativado que trata o esgoto do Campus I da USP/São Carlos e de contribuições domésticas. Os ensaios foram do tipo batelada com recirculação do esgoto durante 4 horas. Também foi avaliada a fotólise (ensaio apenas com radiação solar) e adsorção do catalisador (ensaio sem luz e com Ti'O IND.2') na oxidação de matéria orgânica e na desinfecção. Foram avaliadas as remoções de matéria orgânica (DQO e COT) e de microrganismos indicadores de contaminação fecal (Clostridium perfringens, coliformes totais, E. coli e colifagos). Os resultados indicaram que a fotocatálise heterogênea foi mais eficiente como método de desinfecção que a fotólise. A resistência dos microrganismos ao processo Ti'O IND.2'/UV, em ordem decrescente, foi: Clostridium perfringens, coliformes totais, E. coli e colifagos. As melhores condições operacionais para inativação de microrganismos no efluente 1 foram: 'alfa' = 2 graus e Q = 22,5 L/h. O ângulo de inclinação da placa teve maior influência na oxidação de COT do efluente 2 do que a vazão. As características físico-químicas dos efluentes tiveram papel importante no resultado final da fotocatálise heterogênea, tanto na oxidação de matéria orgânica como na desinfecção. A concentração inicial de E. coli exerceu maior influência na desinfecção fotocatalítica do que a radiação solar, para as condições dos ensaios realizados. Os reatores de placa plana com Ti'O IND.2' imobilizado, quando expostos à luz solar, devem ser vedados para evitar evaporação excessiva / The heterogeneous photocatalysis with Ti'O IND.2' and solar radiation in secondary wastewater treatment to remove organic matter and microorganisms was investigated. A glass plate (approximate 0.48 'M POT.2') with immobilized titanium dioxide (10 g/'M POT.2') was operated in different flow rates (15; 22.5 and 30 L/h) and angles in relation to horizontal (2, 12 and 22 degrees). Two effluents were used in the assays. The first (effluent 1) was from an anaerobic reactor treating sewage and the second (effluent 2) from an anaerobic/aerobic granular activated carbon expanded bed reactor which receives the wastewater collected in the Campus of USP/São Carlos and from the surrounding neighborhood of the campus. The assays were carried out in batch with recirculation time of 4 hours. The photolysis (only solar radiation) and the catalyst adsorption (Ti'O IND.2' in the dark) in organic matter removal and disinfection were evaluated. The oxidation of organic matter (COD and TOC) and inactivation of indicators of fecal contamination (Clostridium perfringens, total coliforms, E. coli, and coliphages) were evaluated. The results shows that heterogeneous photocatalysis was more efficient in effluents disinfection than the photolysis. The resistance of the microorganisms to Ti'O IND.2'/UV process was in decreasing order: Clostridium perfringens, total coliforms, E. coli and coliphages. The best operational conditions for microorganisms inactivation in effluent 1 are: 'alfa' = 2 degrees and Q = 22.5 L/h. TOC oxidation in effluent 2 was more influenced by angle than by flow rate. The physical and chemical characteristics of the effluents had an important role in oxidation and disinfection. Initial E. coli concentration was more important than intensity of solar radiation during photocatalytic disinfection in the experimental conditions of this work. The reactors with immobilized Ti'O IND.2' open to solar radiation have to be closed to avoid excessive evaporation desinfecção dióxido de titânio disinfection fotocatálise heterogênea heterogeneous photocatalysis radiação solar solar radiation titanium dioxide tratamento de esgoto wastewater treatment
482	Investigação de parâmetros hiperfinos dos óxidos semicondutores SnO2 e TiO2 puros e dopados com metais de transição 3d pela espectroscopia de correlação angular gama-gama perturbada / Investigation of hyperfine parameters in pure and 3d transition metal doped SnO2 and TiO2 by means of perturbed gamma-gamma angular correlation spectroscopy Schell, Juliana 19 February 2015 (has links) O presente trabalho teve como objetivo utilizar a técnica nuclear de Correlação Angular γ-γ Perturbada (CAP) para a medida de interações hiperfinas em filmes finos e amostras em pó de óxidos semicondutores SnO2 e TiO2 puros e dopados com metais de transição para uma investigação sistemática de defeitos estruturais e do magnetismo sob o ponto de vista atômico tendo como principal motivação a candidatura à aplicação desses óxidos em spintrônica. O trabalho também teve como foco a preparação e caracterização das amostras por meio de técnicas convencionais, como difração de raios X, microscopia eletrônica de varredura, espectroscopia de energia dispersiva e medidas de magnetização. Amostras puras dos filmes foram medidas mediante a variação sistemática da temperatura de tratamento térmico e do campo magnético aplicado. Tais medidas foram realizadas no HISKP, na Universidade de Bonn (Rheinische Friedrich-Wilhelms-Universität Bonn), através de implantação de íons de 111In(111Cd) ou 181Hf(181Ta); no IPEN, por sua vez, essas medidas foram realizadas após a difusão dos mesmos núcleos de prova. Outra parte das medidas CAP foram feitas através de implantação de íons de 111mCd(111Cd) e 117Cd(117In) no Isotope Mass Separator On-Line (ISOLDE) do Centre Européen Recherche Nucléaire (CERN). As medidas foram realizadas nos intervalos de temperatura de 8 K a 1173 K. Para análise de ferromagnetismo, medidas foram feitas à temperatura ambiente com e sem aplicação de campo magnético externo. Após a comparação dos resultados das medidas macroscópicas e atômicas das amostras, foi possível concluir que há uma correlação entre os defeitos, o magnetismo e a mobilidade dos portadores de carga nos semicondutores aqui estudados. Um passo adiante na busca de semicondutores, cujo ordenamento magnético possibilite o seu uso na eletrônica baseada em spin. Alguns resultados já foram publicados, incluindo resultados obtidos na Universidade de Bonn durante o período de doutorado sanduíche [1-7]. / This study aimed the use of nuclear technique Perturbed γ-γ Angular Correlation Spectroccopy (PAC) to measure the hyperfine interactions in thin films and powder samples of SnO2 and TiO2 pure and doped with transition metals to obtain a systematic investigation of defects and magnetism from an atomic point of view with the main motivation the application in spintronics. The work also focused on the preparation and characterization of samples by conventional techniques such as X-ray diffraction, scanning electron microscopy, energy dispersive spectroscopy and magnetization measurements. Pure samples of the films were measured by the systematic variation of thermal treatment and applied magnetic field. These measurements were performed in HISKP at the University of Bonn (Rheinische Friedrich-Wilhelms-Universität Bonn) using 111In(111Cd) or 181Hf (181Ta); at IPEN, in turn, these measurements were performed after the diffusion of the same probe nuclei. Another part of PAC measurements were carried out using 111mCd(111Cd) and 117Cd (117In) in Isotope Mass Separator On-Line (ISOLDE) at Centre Européen Recherche Nucléaire (CERN). The measurements were performed from 8 K to 1173 K. After comparing results from macroscopic techniques with those from PAC, it was concluded that there is a correlation between the defects, magnetism and the mobility of charge carriers in semiconductors studied here. A step forward in the search for semiconductors, whose magnetic ordering allows its use in electronics based on spin. Some results have been published, including results obtained at the University of Bonn for the sandwich doctorate period [1-7]. diluted magnetic semiconductors PAC spectroscopy semicondutores magnéticos diluídos SnO2 tin dioxide TiO2 titanium dioxide
483	Nitrogen Doped Titanium Dioxide in the Photocatalytic Degradation of Methylene Blue Upadhyaya, Ashraya 01 May 2018 (has links) Titanium dioxide(TiO2) is a stable, effective and well-known photocatalyst for degradation of pollutants. However, its practical applications are limited due to the need for energy higher than 3.2 eV, or a wavelength lower than 390 nm (high frequency waves, ultraviolet and above) hindering its ability to effectively work in the visible light region (about 400 nm to 700 nm). Nitrogen-doped TiO2 (N-TiO2) has garnered some attention as a photocatalyst as it appears to work even in the visible light region. This could allow the utilization of a larger part of the solar spectrum. This thesis presents the results of photocatalytic degradation of methylene blue (MB) carried out under simulated visible light by using TiO2 and N-TiO2(doped in the lab) to evaluate and compare their efficiencies under similar conditions. Civil and Environmental Engineering
484	Développement par procédé plasma de couches minces de type TiO2 dopé à l'azote pour la production d'hydrogène par photo-électrolyse de l'eau sous lumière solaire / Development by plasma processe of nitrogen doped TiO2 thin layersfor hydrogen production by water photo-electrolysis under solar energy Youssef, Laurène 19 November 2018 (has links) Le couplage direct de la séparation et de la photo-catalyse en utilisant des membranes à base de dioxyde de titane, est une approche intéressante habituellement appliquée dans les dispositifs de traitement de l'eau, et récemment envisagée pour d’autres applications, telle que la production d’hydrogène par photo-électrolyse de l’eau. En effet, le dioxyde de titane (TiO2) est bien connu pour ses propriétés photo-catalytiques. En outre, s’il est immobilisé sur support membranaire plutôt qu’utilisé en suspension, son intégration en procédé de séparation est facilitée, sans compter les gains apportés au procédé en termes de compacité, d’intégrité et de capacité séparative. Pour une telle application, des cellules originales sous forme de multicouches sont requises. Certains systèmes sont décrits dans la littérature mais aucun d’entre eux n’est réellement intégré (c’est-à-dire basé sur une géométrie de type multicouche micro-architecturée), ni formé de couches minces obtenus par procédés plasma. Or les procédés plasma sont généralement compétitifs pour l’obtention de systèmes multicouches de hautes intégrité et compacité. Dans le cadre de récents travaux menés à l’IEM, différents types de couches minces ont été préparés par PECVD (Plasma Enhanced Chemical Vapor Deposition), à savoir des films de TiO2 connus pour leurs propriétés photo-catalytiques et des membranes phosphoniques de conduction protonique avérée. En outre, des films minces de platine efficaces pour la réduction catalytique des protons en hydrogène peuvent être également déposés par un autre procédé plasma, la pulvérisation cathodique. Au cours de ce travail de thèse, des films de TiO2 obtenus par PECVD Basse Fréquence sont optimisés en termes d’activité photo-catalytique et de propriétés séparatives; cette optimisation, qui concerne le dopage à l’azote du TiO2 (permettant le déplacement de la bande interdite de la région UV vers la région visible), est le premier objectif de ce projet de thèse. Les films minces sont caractérisés du point de vue de leurs propriétés structurales et fonctionnelles. Le second objectif de la thèse est de montrer l’intérêt de ces films de TiO2 dans la production/séparation d’hydrogène par voie solaire. Dans ce but, la photo-activité des films dans le noir, sous UV et sous visible est étudiée dans une cellule mono-compartiment où les deux électrodes baignent dans un électrolyte liquide. Des études électrochimiques plus poussées en présence d’une membrane électrolyte commerciale et d’une cathode de platine (dont les caractérisations en propre sont portées en annexes de ce travail), sont aussi abordées. Le dernier objectif de cette thèse est le transfert de la technologie des procédés plasma de l’Institut Européen des Membranes de l’Université de Montpellier vers le Laboratoire Chimie-Physique des Matériaux de l’Université Libanaise. Les détails de l’installation du réacteur au Liban font l’objet du dernier chapitre de la thèse ainsi que les résultats des premiers tests de dépôt sur la base de conditions opératoires précédemment optimisées à l’Institut Européen des Membranes. / Direct coupling of separation and photo-catalysis using membranes based on titanium dioxide, is an interesting approach usually applied in water treatment devices, and recently considered for other applications, such as hydrogen production by water photo-electrolysis. Indeed, titanium dioxide (TiO2) is well-known for its photo-catalytic properties. In addition, if it is immobilized on membrane supports rather than used in suspensions, its integration in the separation process is facilitated and some advantages of the process in terms of compactness, integrity and separation capacity are provided. For such an application, original multilayered cells are required. Some systems are described in the literature but none of them is truly integrated (that is to say based on a micro-architecture geometry of multi-layer type) or formed of thin layers obtained by plasma processes. Now plasma processes are generally competitive for obtaining multilayered systems with high integrity and compactness. As part of recent works at IEM, various types of thin films were prepared by PECVD (Plasma Enhanced Chemical Vapor Deposition) to include TiO2 films known for their photo-catalytic properties and phosphonic acid membranes with average protons conductivity. In addition, effective platinum thin films for the protons catalytic reduction into hydrogen could also be deposited by another plasma process, sputtering. In this work, TiO2 films obtained by Low Frequency PECVD are optimized in terms of photo-catalytic activity and separation properties; this optimization, regarding the nitrogen doping of TiO2 (for the band gap shifting from the UV region to the visible region), is the first objective of this thesis project. The thin films structural and functional properties are characterized.The second aim of this thesis is to demonstrate the competitiveness of these films for the Hydrogen production/separation by solar energy. To this end, the layers photo-response has been tested in the dark, under UV and under visible light in a mono-compartment cell where both electrodes are immersed in a liquid electrolyte. Further studies integrating the TiO2 layers in contact with a commercial electrolyte membrane and a platinum counter-electrode (whose characterizations are presented in annexes), are also performed. The last aim of this work is the Plasma technology transfer from the European Membrane Institute of University of Montpellier to the Laboratory of Physical Chemistry of Materials of Lebanese University. The installation and configuration details are presented in the last chapter as well as the results of the first depositions based on operating conditions already optimized at European Membrane Institute. Hydrogène Dioxyde de titane Procédé plasma Production Voie solaire Dopage à l'azote Hydrogen Titanium dioxide Plasma process Production Solar energy Nitrogen doping
485	Computational Investigation of Dye-Sensitized Solar Cells Nilsing, Mattias January 2007 (has links) Interfaces between semiconductors and adsorbed molecules form a central area of research in surface science, occurring in many different contexts. One such application is the so-called Dye-Sensitized Solar Cell (DSSC) where the nanostructured dye-semiconductor interface is of special interest, as this is where the most important ultrafast electron transfer process takes place. In this thesis, structural and electronic aspects of these interfaces have been studied theoretically using quantum chemical computations applied to realistic dye-semiconductor systems. Periodic boundary conditions and large cluster models have been employed together with hybrid HF-DFT functionals in the modeling of nanostructured titanium dioxide. A study of the adsorption of a pyridine molecule via phosphonic and carboxylic acid anchor groups to an anatase (101) surface showed that the choice of anchor group affects the strength of the bindings as well as the electronic interaction at the dye-TiO2 interface. The calculated interfacial electronic coupling was found to be stronger for carboxylic acid than for phosphonic acid, while phosphonic acid binds significantly stronger than carboxylic acid to the TiO2 surface. Atomistic and electronic structure of realistic dye-semiconductor interfaces were reported for RuII-bis-terpyridine dyes on a large anatase TiO2 cluster and perylene dyes on a periodic rutile (110) TiO2 surface. The results show strong influence of anchor and inserted spacer groups on adsorption and electronic properties. Also in these cases, the phosphonic acid anchor group was found to bind the dyes significantly stronger to the surface than the carboxylic acid anchor, while the interfacial electronic coupling was stronger for the carboxylic anchor. The estimated electron injection times were twice as fast for the carboxylic anchor compared to the phosphonic anchor. Moreover, the electronic coupling was affected by the choice of spacer group, where unsaturated spacer groups were found to mediate electron transfer more efficiently than saturated ones. Quantum chemistry titanium dioxide anatase rutile pyridine perylene nanostructured interface electronic coupling electron injection quantum chemistry phosphonic acid Kvantkemi
486	Titanium Dioxide Photocatalysis in Biomaterials Applications Cai, Yanling January 2013 (has links) Despite extensive preventative efforts, the problem of controlling infections associated with biomedical materials persists. Bacteria tend to colonize on biocompatible materials and form biofilms; thus, novel biomaterials with antibacterial properties are of great interest. In this thesis, titanium dioxide (TiO2)-associated photocatalysis under ultraviolet (UV) irradiation was investigated as a strategy for developing bioactivity and antibacterial properties on biomaterials. Although much of the work was specifically directed towards dental materials, the results presented are applicable to a wide range of biomaterial applications. Most of the experimental work in the thesis was based on a resin-TiO2 nanocomposite that was prepared by adding 20 wt% TiO2 nanoparticles to a resin-based polymer material. Tests showed that the addition of the nanoparticles endowed the adhesive material with photocatalytic activity without affecting the functional bonding strength. Subsequent studies indicated a number of additional beneficial properties associated with the nanocomposite that appear promising for biomaterial applications. For example, irradiation with UV light induced bioactivity on the otherwise non-bioactive nanocomposite; this was indicated by hydroxyapatite formation on the surface following soaking in Dulbecco’s phosphate-buffered saline. Under UV irradiation, the resin-TiO2 nanocomposite provided effective antibacterial action against both planktonic and biofilm bacteria. UV irradiation of the nanocomposite also provided a prolonged antibacterial effect that continued after removal of the UV light source. UV treatment also reduced bacterial adhesion to the resin-TiO2 surface. The mechanisms involved in the antibacterial effects of TiO2 photocatalysis were studied by investigating the specific contributions of the photocatalytic reaction products (the reactive oxygen species) and their disinfection kinetics. Methods of improving the viability analysis of bacteria subjected to photocatalysis were also developed. titanium dioxide photocatalysis bioactivity antibacterial effect metabolic activity assay biofilm reactive oxygen species disinfection kinetics post-UV
487	Plant Extract Sensitised Nanoporous TiO2 Thin Film Photoelectrochemical Cells Hedbor, Sigrid, Klar, Linnéa January 2005 (has links) För att undersöka skillnad i prestationsförmåga mellan celler sensiterade med växtextraktsbaserad färg, och celler sensiterademed ruteniumkomplex-baserad färg, samt huruvida presskraften påverkar en cells prestationsförmåga, tillverkades icke-slutna fotoelektrokemiska färg-sensiterade solceller med tunnfilmsfotoelektroder av pressad, nanoporös titandioxid. Cellerna pressades med tre olika presskrafter och sensiterades med växtextraktsfärg från rödkål, rödbeta, viol och henna, samt en ruteniumkomplex-baserad färg som fick utgöra kontrollbetingelse. För varje cell uppmättes IPCE- och iV-värde och motsvarande fyllnadsgrad (fill factor) och dessa jämfördes. Ingen signifikant skillnad kunde fastställas mellan celler pressade med olika presstryck. Bland cellerna sensiterade med växtextraktbaserad färg presterade rödbeta bäst. Cellen med högst effektivitet hade fyllnadsgraden 70%. Emellertid uppvisade de växtfärgade cellerna genomgående sämre effektivitet än de rutenium-sensiterade och fotoströmmarna var mycket låga. IPCE-värdena var allmännt låga: den bäst presterande cellen hade ett IPCE-värde på något över 0,06 i våglängdsintervallet 440-470 nm. En förklaring till detta är de övriga ämnen som förutom pigment återfinns i de växtbaserade färgerna. Dessa hindrar pigmentmättnad och förhindrar att växtfärgen når ruteniumfärgens intensitet. En annan anledning består i svårigheten att passa ihop energinivåerna i cellens elektrolyt-halvledarsystem med energinivåerna hos pigmentet i växtfärgen. / Non-sealed photoelectrochemical dye sensitised solar cells (DSSC) with pressed nanoporous TiO2 thin film photoelectrodes were manufactured for the purposes of finding out whether plant extractbased dye sensitised cells can perform as well as ruthenium complex-based dye sensitised cells and whether the pressing force affects the cell performance. The cells were pressed with three different pressing forces and sensitised with plant extracts from red cabbage, beetroot, violet and henna, as well as with a ruthenium complex-based dye for comparison. The IPCE and iV values and the corresponding fill factors of the cells were evaluated and compared. No significant difference between the cells pressed with different pressing forces could be established. Among the plant extract-based dye sensitised cells the ones sensitised with beetroot extract performed best. The cell that achieved the highest efficiency had a fill factor of 70%. Compared to the ruthenium-sensitised cells the overall performance of the plant dye sensitised cells were very poor and the produced photocurrents very low. The IPCE values were generally low: one of the best-performing cells had an IPCE value of slightly over 0.06 in the 440-470 nm wavelength ranges. One reason for this is that it is difficult to obtain a plant extract dye as intense and deep in colour as ruthenium complex-based dyes, since pigment saturation is obstructed by the presence of other chemical compounds in the plant extracts. Another is that it is a delicate and difficult matter to match the energy levels in the electrolyte-semiconductor system with the energy levels of the pigments in the plant extract dye. photoelectrochemical cell solar cell nanoporous thin film titanium dioxide dye sensitised ruthenium plant extract beetroot. TECHNOLOGY TEKNIKVETENSKAP
488	Design and Characterization of Materials and Processes for Area Selective Atomic Layer Deposition Sinha, Ashwini K. 27 October 2006 (has links) Area selective atomic layer deposition (ASALD) is demonstrated to be a promising route to perform direct patterned deposition. In particular, methods to modify (or mask) the surface and process parameters to perform selective deposition of titanium dioxide have been developed and investigated in detail. Results indicated that self assembled monolayer based masking methodology posses significant limitations due to challenges associated with obtaining defect free monolayer and absence of traditional patterning techniques. On the other hand, polymer films based masking methodology offer a better alternative to perform ASALD. A number of factors that must be considered in designing a successful ASALD process based on polymer films were identified. These include: reactivity of polymer with ALD precursor, diffusion of ALD precursors through polymer mask and remnant precursor content in the polymer film during ALD cycling. Investigations suggested that ALD nucleation can be successfully blocked on polymer films that do not contain direct OH sites in their backbone. It was observed that sorption of water in the polymer film does not pose a serious limitation however; metal precursor diffusion through the polymer mask was identified as a critical parameter in determining the minimum required masking layer thickness for a successful ASALD process. In addition, a novel ASALD-based top surface imaging (TSI) technique has been developed. The ASALD-TSI process has demonstrated sharp contrast (etch barrier deposition vs exposure dose) and therefore offers the potential to overcome many of the challenges experienced with conventional TSI schemes. Atomic layer deposition Polymer thin films Top surface imaging Titanium dioxide Quartz crystal microbalance Thin films Monomolecular films Masks (Electronics)
489	Photocatalytic And Photoelectrochemical Water Splitting Over Ordered Titania Nanotube Arrays Karslioglu, Osman 01 February 2009 (has links) (PDF) The objective of this study was to investigate photocatalytic water splitting over ordered TiO2 nanotube arrays. Synthesis of ordered nanotube arrays of titania, as a micron thick film on a titanium foil was accomplished by electrochemical anodization methods defined in the literature. Effect of two types of electrolyte (aqueous and organic) on the micro-morphology was observed by scanning electron microscopy. Optimum anodization times for the TiO2 nanotube electrodes, synthesized in ethylene glycol electrolyte, were different for acidic and basic electrolytes. Optimum times were determined as 2 hours in acidic and 4 hours in basic solutions. An H-type cell was constructed using a two side anodized titanium foil aiming the photocatalytic, stoichiometric and separate evolution of H2/O2 from the splitting of water. Gas evolution was observed at a rate of approximately 1 mL/h in the anode and 0.5 mL/h in the cathode, which implied the reverse of the desired stoichiometry. As the surface was corroded in that experimental conditions, electrochemical properties of the synthesized films were investigated by cyclic voltammetry (CV) at milder conditions. CV showed the reduction of Ti4+ to Ti3+, beginning at -0.2 V (vs. Ag/AgCl). Since the process is accompanied by proton intercalation to the oxide, non-annealed samples showed higher currents in that region. Non-annealed samples showed no photocurrent. Photocurrents obtained in this work, on the average 0.1-0.2 mA/cm2, were one order of magnitude lower than the similar studies in the literature. TP Chemical Engineering 155-156
490	Adsorption Of Aromatic Molecules On Rutile Tio2(110) Surfaces Mesta, Murat 01 September 2009 (has links) (PDF) Transition metal oxides having high dielectric constants and wide band gaps find very important and interesting technological applications in surface physics. In particular, titania is the most commonly used material in heterogeneous catalysis because of its stable and flat surfaces. Having Ti cations at different charge states within the system brings about various novel electronic properties which are mainly surface related. Adsorption of catalytically important or chemically useful molecules on titania surfaces are investigated, electronic energy bands and charge densities are calculated from first principles using the density functional theory in the GGA scheme. The comparisons with the leading theories and existing experimental data are maid.

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