The Impact of Curing Temperature on the Hydration, Microstructure, Mechanical Properties, and Durability of Nanomodified Cementitious Composites

Dan Huang (13169919)

28 July 2022

<p>The study focused on examining the effects of using nanoadditives (nano-TiO2 and colloidal silica) on the hydration kinetics, microstructure, mechanical properties, and durability of concretes, especially those containing fly ash and slag and cured at low (4°C) temperature. </p> <p>The results of the Vicat and isothermal calorimetery (IC) tests suggest that the addition of nano-TiO2 accelerates the hydration process of pastes. In addition, the results of the thermogravimetric analysis (TGA) indicated that the addition of nano-TiO2 increased the amount of hydration products in the pastes, with more notable increases observed in fly ash pastes. Moreover, X-ray diffraction (XRD) results revealed that the addition of nano-TiO2 reduced the mean size of calcium hydroxide (CH) crystals.  </p> <p>The interfacial transition zone (ITZ) of concretes with nano-TiO2 was found to be less cracked and less porous when compared to that of concrete without nano-TiO2. Furthermore, the energy dispersive X-ray (EDX) analyses of the outer hydration products around partially hydrated cement particles in fly ash concretes with nano-TiO2 revealed reduction in the values of Ca/Si atomic ratios when compared to the reference fly ash concrete. The image analysis results of the concrete air void system indicated slightly reduced air content, increased specific surface area (SSA), and decreased spacing factor (SF) in concretes with added nano-TiO2. </p> <p>The addition of nano-TiO2 was also found to enhance the compressive and flexural strengths of mortars and concretes. Nano-TiO2 also improved the resistivity and formation factor values of concretes containing fly ash. Moreover, the total volume of pores, as well as the values of water absorption, were also reduced as a result of addition of nano-TiO2. This was true for all types of concretes (i.e., with or without SCMs). Finally, the use of nano-TiO2 seemed to be more beneficial with respect to improving the scaling and freeze-thaw resistance of fly ash concretes compared to cement-only and slag concretes. </p> <p>Concretes with added nanosilica (colloidal silica) also developed higher compressive and flexural strengths when compared to reference concrete. Moreover, the total pores and permeability of concretes decreased due to the addition of nanosilica while the improvement in scaling resistance of these concretes was only slight. Furthermore, concretes with nanosilica were found to have higher percentage of finer air voids compared to reference concretes. Finally, the ITZ of concretes with nanosilica was found to have fewer defects and cracks compared to the reference concrete. </p> <p>In summary, this dissertation presents the results of a study on the multi-scale behavior of nanomodified concretes with and without SCMs cured at both room and low temperatures. Knowledge gained from this study would be helpful in developing concretes with denser and less porous microstructure, a more refined and better-distributed air void system, improved strength, reduced permeability, and enhanced scaling and freeze-thaw resistance, especially in cases when involving the use of SCMs and exposure to low early-age temperatures.</p>

Civil geotechnical engineering

Nanomaterials

concrete

nano-TiO2

supplementary cementitious materails

fly ash

slag cement

nanosilica

scaling

durability

Development of Cellulose-Titanium dioxide-Porphyrin Nanocomposite Films with High-barrier, UV-blocking, and Visible Light-Responsive Antimicrobial Features

Lovely, Belladini

03 June 2024

The packaging does not serve as a mere containment but also can be designed to play a key role in preserving the product from quality-deteriorating factors, including oxygen, light irradiation, and foodborne pathogenic microorganisms (e.g., Escherichia coli). There has been a growing interest in employing ultra-porous metal-organic frameworks (MOF) with visible light-responsive antibacterial mechanisms to generate reactive oxygen species (ROS) that can eliminate bacteria via an oxidative burst. MOF is made of inorganic metal ions/nodes/clusters/secondary building units linked by organic bridge ligands, where titanium dioxide (TiO2) and tetrakis(4-carboxyphenyl)porphyrin) (TCPP) were selected for these components, respectively. TiO2 is an exceptional UV-A/B/C-blocker; meanwhile, TCPP dye performs a remarkable photocatalytic ability even under visible light, on top of its macro-heterocyclic structure that is ideal as a MOF linker. Both have good compatibility but suffer from the notorious tendency to self-quench/aggregate. The incorporation of MOF-based conjugates into a polymeric matrix, like cellulose, is among the proven-successful solutions. Cellulose is the Earth's most abundant and naturally biodegradable, and cellulose nanofibril (CNF) was particularly chosen for its high specific surface area and surface activity. However, a straightforward, cheap, and environmentally friendly approach of multicycle homogenization (0-25 passes) was conducted to solve neat cellulose's challenge of natural hydrophilicity, where low pressure (<10 MPa) was applied to prevent the common over-shearing effect. The antibacterial efficacy of CNF films functionalized with TiO2-TCPP conjugate on inhibiting E. coli growth was analyzed with and without light of different intensities (3000 and 6000 lux). The positive impacts of CNFs' promoted fibrillation and subsequent inter/intra-molecular hydrogen bonding post-homogenization were evidenced in an array of functional properties, i.e., crystallinity, TiO2-TCPP conjugate dispersion, surface smoothness, mechanical properties, thermal stability, hydrophobicity, oxygen barrier (comparable to ethylene-vinyl alcohol (EVOH), a commercial high-barrier polymer), and 100%-antibacterial rate (under 6000 lux after 72 hours). Varying optimum cycles of homogenization demonstrated the prospect of the proposed homogenization approach in preparing CNF with diverse processability and applicability. These findings also exhibited a promising potential for a myriad of high-barrier, UV-blocking, and/or visible light-responsive antibacterial film applications, including food packaging and biomedical. / Doctor of Philosophy / Packaging is useful not only as a container but can also be designed to help prevent products from being spoiled due to various reasons such as oxidation, light, and bacterial contamination. Researchers have discovered the promising antibacterial feature of the metal-organic framework (MOF). Packaging made with MOF technology can harness light and oxygen in the environment to produce a special form of oxygen called reactive oxygen species (ROS) that can kill unwanted bacteria. MOF is an extremely porous sponge-like material made of two ingredients: an inorganic metal cluster and an organic linker; in this study, titanium dioxide (TiO2) and a porphyrin called TCPP were selected, respectively. TiO2 is an excellent ultraviolet blocker, while TCPP has a unique, ring-like geometry that is ideal for use as a linker and an antimicrobial feature that works well under the visible light spectrum. The pair are compatible but still suffer from MOF's notorious challenge, where it tends to clump together because of its tiny size. To resolve this problem, TiO2-TCPP MOF can be deposited evenly in a cast made of polymer. Cellulose has been proven to work effectively as a polymeric cast; moreover, it is natural, biodegradable, and in abundant supply. A type of nanosized cellulose—cellulose nanofibril (CNF)—was specifically chosen because its high surface area and activity are useful when blended with other materials. However, cellulose is naturally a poor water-repellant that is not ideal for packaging applications. As a solution, cellulose can be treated with a homogenization technique by passing the material through a very narrow hole under high pressure. Homogenization can be problematic as it possibly damages the cellulose's structure, and its high pressure can also be expensive and energy consuming. Therefore, low pressure with multiple cycles was applied in this work. CNF-TiO2-TCPP films were tested for their ability to slow down E. coli bacteria growth with and without light of varying brightness to compare its light-sensitive antimicrobial feature. Homogenization was found helpful in producing higher-quality CNF, which improved several of the film's final characteristics, including an even material dispersion, structural order, smoothness, strength, heat resistance, and water repellency. Most importantly, it produced films with oxygen barrier ability comparable to commercial high-barrier plastics and completely eliminated bacteria after 72 hours. The optimum number of homogenization cycles was found to be dependent on the desired characteristics and application. Overall, these findings carry a promising potential for a variety of applications, including food packaging and the biomedical field.

Cellulose nanofibrils (CNF)

Titanium dioxide (TiO2)

Photosensitive antibacterial agents

Homogenization cycles/passes

Exposure to Nanomaterials Results in Alterations of Inflammatory and Atherosclerotic Signaling Pathways in the Coronary Vasculature of Wildtype Rodents

Davis, Griffith M.

08 1900

Cardiovascular disease (CVD) is the leading cause of death for people of most ethnicities on a global scale, and countless research efforts on the pathology of CVD has been well-characterized over the years. However, advancement in modern technologies, such as nanotechnology, has generated environmental and occupational health concerns within the scientific community. Current investigation of nanotoxicity calls into question the negative effects nanomaterials may invoke from their environmental, commercial, and therapeutic usage. As a result, further research is needed to investigate and characterize the toxicological implications associated with nanomaterial-exposure and CVD. We investigated the toxicity of multi-walled carbon nanotubes (MWCNT) and titanium dioxide (TiO2), which are two prominently used nanomaterials that have been previously linked to upregulation of inflammatory and atherogenic factors. However, the mechanistic pathways involved in these nanomaterials mediating detrimental effects on the heart and/or coronary vasculature have not yet been fully determined. Thus, we utilized two different routes of exposure in rodent models to assess alterations in proinflammatory and proatherogenic signaling pathways, which are represented in contrast throughout the dissertation. In our MWCNT study, we used C57Bl/6 mice exposed to MWCNTs (1 mg/m3) or filtered air (FA-Controls), via inhalation, for 6 hr/d for 14d. Conversely, intravenous TiO2 was administered to F344 male fisher rats, following 24h and 28d post-exposure to a single injection of TiO2-NPs (1 mg/kg), compared to control animals. MWCNT-exposed endpoints investigated the alterations in cholesterol transport, such as lectin-like oxidized low-density lipoprotein receptor (LOX)-1 and ATP-binding cassette transporter (ABCA)-1, inflammatory markers [tumor necrosis factor (TNF)-α], interleukin (IL)-1β/IL-6, nuclear-factor kappa-light-chain-enhancer of activated B cells (NF-κB) and signaling factors involved in activation of the pathway, as well as intracellular/vascular adhesion molecule(s) (VCAM-1, ICAM-1), and miRNAs (miR-221/-21/-1), associated with CVD, were analyzed in cardiac tissue and coronary vasculature. Cardiac fibrotic deposition, matrix-metalloproteinases (MMP)-2/9, and reactive oxygen species (ROS) were also assessed. TiO2-exposure endpoints also involved alterations on cholesterol transport proteins via LOX-1 and ABCA-1, factors of inflammation, namely intracellular macrophages and interleukin (IL)-1β, MMP-2/9 activity and protein expression, fibrotic deposition, and ROS generation were analyzed via quantitative detection or histologically in both cardiac tissue and coronary vasculature. Results from both studies found alterations in fibrotic deposition, upregulation in LOX-1 expression and MMP-2/9 activity, and ROS generation; with a concurrent decrease in ABCA-1 expression in cardiac tissue and coronary vasculature. Individually, MWCNT-exposed endpoints had shown induction of cardiac TNF-α, MMP-9, IκB Kinase (IKK)-α/β, and miR-221 mRNAs; as well as increased coronary expression of TNF-α and VCAM-1. TiO2 studies found increases in IL-1β and MMP-9 protein expression, as well as intracellular macrophage induction. Both studies also found, through pre-treatment of NADPH oxidase inhibitor, apocynin, resulted in attenuation of nanomaterial-exposure mediated ROS production; with nitric oxide synthase inhibitor, L-NNA, also showing attenuation, but only in our MWCNT-exposed inhalation study. The results from both studies have demonstrated, through different routes of administration, exposures, and rodent models; that exposure to nanomaterials can mediate signaling pathways involved in initiation and/or progression of CVD.

Nanotoxicity

MWCNTs

TiO2

coronary vessels

ROS

Nanostructured materials -- Toxicology.

Cardiovascular system -- Diseases.

Atherosclerosis -- Animal models.

Mice -- Cardiovascular system.

Nanocrystalline Titania Based Dye Sensitized Solar Cells - Effect Of Electrodes And Electrolyte On The Performance

Mathew, Ambily

07 1900

Dye-sensitized solar cells (DSC) have attracted considerable scientific and industrial interest during the past decade as an economically feasible alternative to conventional photovoltaic devices. DSCs have the potential to be as efficient as silicon solar cells, but at a fraction of the cost of silicon solar cells. The unique advantage of DSC compared to conventional solar cells is that the light absorption, electron transport and hole transport are handled by different components which reduces the chance of recombination. In the present work, to facilitate DSC with good energy conversion efficiency, its performance have been evaluated as a function of titania layer morphology, redox couple concentration and the catalytic layer on the counter electrode. The results that are obtained in the present investigations have been organized as follows Chapter 1 gives a brief exposure to DSC technology. Special emphasize has been on the structure and individual components of the DSC. Chapter 2 describes various experimental techniques that are employed to fabricate and characterize DSCs under study. Chapter 3 presents a systematic study of the characteristics of DSC made of three different types of electrodes namely: TiO2 nanotubes (TNT) which have excellent electron transport properties, TiO2 microspheres (TMS) which possess high surface area and light scattering ability and TiO2 nano particles (TNP) possessing high surface area. The electronic, morphological, optical and surface properties of individual electrodes are studied. The highest efficiency of 8.03% is obtained for DSCs prepared with TMS electrodes. A higher value of effective diffusion coefficient (Deff) and diffusion length (Ln) of electrons as obtained by electrochemical impedance spectroscopy (EIS) analysis confirms a high charge collection efficiency in microsphere based cell. Chapter 4 gives a detailed study of DSCs fabricated with a tri-layer photo anode with TNTs as light scattering layer. The tri-layer structure has given an enhanced efficiency of 7.15% which is 16% higher than TNP based cell and 40% higher than TNT based cells. Chapter 5 deals with the investigations on the effect of concentration of redox couple on the photovoltaic properties of DSC for different ratios of [I2] to [LiI] (1:2, 1:5 and 1:10) with five viii concentrations of I2 namely 0.01 M, 0.03 M, 0.05 M, 0.08 M and 0.1M in acetonitrile. It is found that the open circuit potential (Voc) decreases with increase in the ratio of redox couple whereas short circuit current density (Jsc) and fill factor (FF) increase. The reason for the decline in Voc is the higher recombination between electrons in the conduction band of TiO2 and the I3- ions present in the electrolyte, induced by the absorptive Li+ ions. In addition using EIS it is found that the τ improves with the increase in [LiI] at a particular [I2], whereas at a fixed [I2]/ [LiI] ratio the increase in [I2] is found to reduce the τ and Deff due to the enhanced recombination. Chapter 6 describes the application of carbon based counter electrode (CE) materials for DSCs. Two counter electrode materials have been investigated namely (1) Multiwalled carbon nanotubes (MWCNT) synthesized by pyrolysis method and (2) Platinum decorated multiwalled carbon nanotubes (Pt/MWCNT) prepared by chemical reduction of platinum precursors. Using Pt/MWCNT composite electrode the DSC achieved an energy conversion efficiency of 6.5 %. From the analysis on symmetric cells, it is found that electro catalytic activity of Pt/MWCNT CE is similar to that of platinum CE, though the platinum loading is very less for the former. This is attributed to the effective utilization of catalyst owing to high surface area arising from the increased surface roughness. Chapter 7 discusses the application of titanium foil in place of glass substrate for the photo anode. The titanium foil offers fabrication of flexible DSC. The performance of DSC with TMS layers and aligned titania nanotube arrays (TNA) prepared by anodization method is studied. Compared to TMS based cell, TNA has given a better efficiency at a lower thickness. Chapter 8 presents the scheme used to seal DSCs and its stability analysis. We have employed the usual hot melt sealing for edge whereas hole sealing is carried out with tooth pick and a UV curable adhesive. The degradation in efficiency is found to be 20% for low efficiency cells whereas, for high efficiency cells it is found to be 45% after 45 days. The leakage of highly volatile acetonitrile through the edge and hole is found to be responsible for the reduction in the performance of the device. Hence a high temperature sealing method is proposed to fabricate stable cells. Chapter 9 gives summary and conclusions of the present work

Dye-Sensitized Solar Cells

Solar Energy

Photovoltaics

Titania Nanostructures

Titania Photoelectrodes

Electrolytes

Counter Electrodes

Electrodes

Carbon Nanotubes

Titania Nanotubes

Photoanodes

Nanocrystalline Dye Solar Cells

Dye-Sensitized Solar Cell (DSC)

TiO2 Nanostructures

TiO2 Nanotubes (TNTs)

Dye Solar Cell

TiO2 Nanoparticles

Dye Sensitized Solar Cells

Applied Physics

Élaboration et caractérisation des couches minces d'oxydes conducteurs transparents (TCO) pour les cellules solaires

Koné, Klègayéré Emmanuel

15 January 2024

[FR] Ce travail rapporte une investigation sur l’élaboration et la caractérisation de quelques oxydes transparents conducteurs, en occurrence l’oxyde de zinc (ZnO), l’oxyde de titane (TiO2) et l’oxyde de nickel (NiO). En revanche, une étude d’hétérojonction d’une couche de pérovskite déposée sur une couche de ZnO a été faite. Le spin coating et le spray pyrolyse qui sont des techniques simples et à faible coût ont été utilisées pour réaliser les différents dépôts. Les films obtenus ont été caractérisés par la Diffraction des Rayons X (DRX), la spectroscopie UV- Visible et la Microscopie Electronique à Balayage (MEB). En vue d’améliorer les propriétés de des oxydes élaborés, plusieurs dépôts ont été effectués. Le premier dépôt a permis de comparer leurs différentes propriétés. L’oxyde de zinc a présenté les meilleures propriétés par rapport aux autres. Il a fait preuve d’une bonne transmittance supérieure à 80%, une bande interdite de plus de 3,25 eV et une bonne cristallinité. Un dépôt a été effectué pour étudier l’influence de la concentration de la solution de ZnO sur ses différentes propriétés. Il est ressorti de cette étude que 0,5 M a donné les meilleurs résultats avec une transmittance de plus de 80% dans le visible et une bande interdite de 3,25 eV. Pour le dépôt de l’étude de l’effet du nombre de couches sur les différentes propriétés, quatre échantillons ont été produits (1 couche, 2 couches, 3 couches et 4 couches). L’échantillon à 4 couches a présenté les plus bons résultats. En plus d’avoir une transparence dans le visible de plus 70% et une bande interdite de 3,25 eV, il possède le plus de grains. Les résultats du dopage de l’oxyde de zinc par l’alumine ont montré que ses propriétés s’améliorent avec le dopage. Ainsi, l’échantillon dopé à 10% a donné de bons résultats comparés aux autres. Sa transmittance est plus de 90% et sa bande interdite est de 3,41 eV. Pour tous les dépôts, les résultats de la diffraction des rayons X ont révélé que l’oxyde de zinc présente deux principaux pics caractéristiques correspondant aux plans cristallographiques (002) et (101). Tous les films de ZnO produits sont polycristallins. Les résultats de l’UV-Visible ont montré que les oxydes élaborés ont une transmittance autour de 80% et une large bande interdite qui varie entre 3,20 eV et 3,41 eV. La perception des grains sur les images MEB a confirmé la cristallinité des films. Les pics identifiés du film de TiO2 correspondent aux plans (101) et (004), tous correspondant à la phase anatase tétragonale du TiO2. L'orientation préférentielle des grains est la direction (101). L’analyse de la DRX de NiO a montré que le pic indexé (111) à 37,636° correspond à la structure cubique des nanoparticules de NiO. Les dépôts de pérovskite sur la couche de ZnO en hétérojonction a révélé une bonne adhésion entre les deux couches. Ces dépôts ont permis d’étudier leurs stabilités et d’initier la fabrication d’une cellule solaire. / [ES] En este trabajo se informa de una investigación sobre el desarrollo y la caracterización de una serie de óxidos conductores transparentes, a saber, óxido de zinc (ZnO), óxido de titanio (TiO2) y óxido de níquel (NiO). Por otra parte, se llevó a cabo un estudio de heterounión de una capa de perovskita depositada sobre una capa de ZnO. Para producir los distintos depósitos se utilizaron técnicas sencillas y de bajo coste, como el recubrimiento por centrifugación y el pirólisis por pulverización. Las películas obtenidas se caracterizaron por difracción de rayos X (DRX), espectroscopia UV-Visible y microscopía electrónica de barrido (SEM). Para mejorar las propiedades de los óxidos producidos, se realizaron varios depósitos. El primer depósito se utilizó para comparar sus diferentes propiedades. El óxido de zinc mostró las mejores propiedades en comparación con los demás. Mostró una buena transmitancia de más del 80%, una brecha de banda de más de 3,25 eV y una buena cristalinidad. Se llevó a cabo una deposición para estudiar la influencia de la concentración de la solución de ZnO en sus distintas propiedades. El estudio demostró que 0,5 M daba los mejores resultados, con una transmitancia superior al 80% en el visible y una separación de banda de 3,25 eV. Se fabricaron cuatro muestras (1 capa, 2 capas, 3 capas y 4 capas) para estudiar el efecto del número de capas en las distintas propiedades. La muestra de 4 capas dio los mejores resultados. Además de tener una transparencia visible superior al 70% y un bandgap de 3,25 eV, presentaba la mayor cantidad de granos. Los resultados del dopaje del óxido de zinc con alúmina mostraron que sus propiedades mejoraban con el dopaje. La muestra dopada al 10% dio buenos resultados en comparación con las demás. Su transmitancia era superior al 90% y su brecha de banda era de 3,41 eV. Para todos los depósitos, los resultados de difracción de rayos X revelaron que el óxido de zinc tiene dos picos característicos principales correspondientes a los planos cristalográficos (002) y (101). Todas las películas de ZnO producidas son policristalinas. Los resultados de UV-Visible mostraron que los óxidos producidos tienen una transmitancia de alrededor del 80% y una amplia banda de separación que varía entre 3,20 eV y 3,41 eV. La percepción de los granos en las imágenes SEM confirmó la cristalinidad de las películas. Los picos identificados en la película de TiO2 corresponden a los planos (101) y (004), todos ellos correspondientes a la fase anatasa tetragonal del TiO2. La orientación de grano preferida es en la dirección (101). El análisis XRD del NiO mostró que el pico indexado (111) a 37,636° corresponde a la estructura cúbica de las nanopartículas de NiO. Los depósitos de perovskita sobre la capa de heterounión de ZnO revelaron una buena adherencia entre ambas capas. Estos depósitos permitieron estudiar su estabilidad e iniciar la fabricación de una célula solar. / [CA] Aquest treball informa d'una investigació sobre l'elaboració i caracterització d'alguns òxids conductors transparents, concretament l'òxid de zinc (ZnO), l'òxid de titani (TiO2) i l'òxid de níquel (NiO). D'altra banda, es va fer un estudi d'heterounió d'una capa de perovskita dipositada sobre una capa de ZnO. Per produir els diferents dipòsits es van utilitzar el recobriment per centrifugació i l'esprai de piròlisi, que són tècniques senzilles i de baix cost. Les pel·lícules obtingudes es van caracteritzar per difracció de raigs X (XRD), espectroscòpia UV-Vis i microscòpia electrònica d'escaneig (SEM). Pero tal de millorar les propietats dels òxids elaborats, s'han realitzat diversos dipòsits. El primer dipòsit va permetre comparar les seves diferents propietats. L'òxid de zinc va mostrar les millors propietats en comparació amb els altres. Va a demostrar una bona transmitància superior al 80%, un interval de banda superior a 3,25 eV i una bona cristalinitat. Es va fer un dipòsit per estudiar la influència de la concentració de la solució de ZnO en les seves diferents propietats. D'aquest estudi es va comprovar que 0,5 M va donar els millors resultats amb una transmitància de més del 80% en el visible i un interval de banda de 3,25 eV. Per a la presentació de l'estudi de l'efecte del nombre de capes sobre les diferents propietats, es van produir quatre mostres (1 capa, 2 capes, 3 capes i 4 capes). La mostra de 4 capes va mostrar els millors resultats. A més de tenir una transparència en el visible de més del 70% i un interval de banda de 3,25 eV, és el que té més grans. Els resultats del dopatge d'òxid de zinc amb alúmina van a demostrar que les seves propietats milloren amb el dopatge. Així, la mostra augmentada al 10% va a donar bons resultats en comparació amb les altres. La seva transmitància és superior al 90% i el seu interval de banda és de 3,41 eV. Per a tots els dipòsits, els resultats de la difracció de raigs X van revelar que l'òxid de zinc presenta dos pics característics principals corresponents als plans cristal·logràfics (002) i (101). Totes les pel·lícules de ZnO produïdes són policristalines. Els resultats UV-Vis van mostrar que els òxids elaborats tenen una transmitància al voltant del 80% i una àmplia banda prohibida que varia entre 3,20 eV i 3,41 eV. La percepció dels grans a les imatges SEM va confirmar la cristalinitat de les pel·lícules. Els pics identificats de la pel·lícula de TiO2 corresponen als plans (101) i (004), tots corresponents a la fase anatasa tetragonal de TiO2. L'orientació preferida del gra és la direcció (101). L'anàlisi XRD de NiO va a mostrar que el pic indexat (111) a 37,636 ° correspon a l'estructura cúbica de les nanopartícules de NiO. Els dipòsits de perovskita a la capa de ZnO d'heterounió van revelar una bona adhesió entre les dues capes. Aquests dipòsits van permetre estudiar la seva estabilitat i iniciar la fabricació d'una cèl·lula solar. / [EN] This work reports on an investigation into the elaboration and characterisation of some of transparent conducting oxides, namely zinc oxide (ZnO), titanium oxide (TiO2) and nickel oxide (NiO). On the other hand, a heterojunction study of a perovskite layer deposited on a ZnO layer was carried out. Spin coating and spray pyrolysis, which are simple, low-cost techniques, were used to produce the various deposits. The films obtained were characterised by X-ray Diffraction (XRD), UV-Visible spectroscopy and Scanning Electron Microscopy (SEM). In order to improve the properties of the oxides produced, several deposits were made. The first deposit was used to compare their different properties. Zinc oxide showed the best properties compared with the others. It showed good transmittance of over 80 %, a band gap of over 3.25 eV and good crystallinity. A deposition was carried out to study the influence of the concentration of the ZnO solution on its various properties. The study showed that 0.5 M gave the best results, with a transmittance of over 80 % in the visible and a band gap of 3.25 eV. Four samples were produced (1 layer, 2 layers, 3 layers and 4 layers) to study the effect of the number of layers on the different properties. The 4-layer sample gave the best results. As well as having a visible transparency of over 70 % and a band gap of 3.25 eV, it had the most grains. The results of doping zinc oxide with alumina showed that its properties improved with doping. The 10 % doped sample gave good results compared with the others. Its transmittance was over 90 % and its band gap was 3.41 eV. For all the deposits, the X-ray diffraction results revealed that the zinc oxide has two main characteristic peaks corresponding to the (002) and (101) crystallographic planes. All the ZnO films produced are polycrystalline. The UV-Visible results showed that the oxides produced have a transmittance of around 80 % and a wide band gap varying between 3.20 eV and 3.41 eV. The perception of the grains on the SEM images confirmed the crystallinity of the films. The peaks identified in the TiO2 film correspond to the (101) and (004) planes, all corresponding to the tetragonal anatase phase of TiO2. The preferred grain orientation is in the (101) direction. XRD analysis of NiO showed that the indexed peak (111) at 37.636° corresponds to the cubic structure of NiO nanoparticles. Deposits of perovskite on the heterojunction ZnO layer revealed good adhesion between the two layers. These deposits were used to study their stability and to initiate the manufacture of a solar cell. / Koné, KE. (2023). Élaboration et caractérisation des couches minces d'oxydes conducteurs transparents (TCO) pour les cellules solaires [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/201922

Oxyde conducteur transparent (TCO)

Propriétés structurelles

Propriétés optiques

Propriétés morphologiques

Oxyde de zinc (ZnO)

Oxyde de titane (TiO2)

Oxyde de nickel (NiO)

Óxido conductor transparente (TCO)

Perovskitas

Propiedades estructurales

Propiedades ópticas

Propiedades morfológicas

Óxido de níquel (NiO)

Óxido de titanio (TiO2)

Óxido de zinc (ZnO)

Transparent Conductive Oxide (TCO)

Thin film

Structural properties

Optical properties

Morphological properties

Zinc oxide (ZnO)

Titanium oxide (TiO2)

Nickel oxide (NiO)

Perovskites

FISICA APLICADA

Effect of nanoparticles on human cells from healthy individuals and patients with respiratory diseases

Osman, Ilham F.

January 2010

Ever increasing applications of nanomaterials (materials with one or more dimension less than 100 nm) has raised awareness of their potential genotoxicity. They have unique physico-chemical properties and so could have unpredictable effects. Zinc oxide (ZnO) and titanium dioxide (TiO2) are widely used in a number of commercial products. There are published studies indicating that some forms of these compounds may be photo-clastogenic in mammalian cells. What has not been investigated before is the effect of nanoparticles from these compounds in human germ cells. Thus the present study has examined their effects in the presence and absence of UV light in human sperm and compared responses to those obtained with human lymphocytes using the Comet assay to measure DNA damage. The effect of nanoparticles (40-70nm range) was studied in human sperm and lymphocytes in the dark, after pre-irradiation with UV and simultaneous irradiation with UV. The studies do provide some evidence that there are photo-genotoxic events in sperm and lymphocytes in the absence of overt toxicity. The cytotoxic and genotoxic potentials of ZnO and TiO2 as well as their effect on phosphotyrosine expression, were examined in the human epithelial cervical carcinoma cells (Hela cells). This was done to try and determine the underlying molecular events resulting from their exposure to ZnO and TiO2 nanoparticles occurring at the same time as DNA is damaged. Concentration- and time-dependent cytotoxicity, and an increase in DNA and cytogenetic damage with increasing nanoparticle concentrations were reported in this study. Mainly for zinc oxide, genotoxicity was clearly associated with an increase in tyrosine phosphorylation. Nanotechnology has raced ahead of nanotoxicology and little is known of the effects of nanoparticles in human systems, let alone in diseased individuals. Therefore, the effects of TiO2 nanoparticles in peripheral blood lymphocytes from patients with respiratory diseases (lung cancer, chronic obstructive pulmonary disease (COPD) and asthma) were compared with those in healthy individuals using genotoxic endpoints to determine whether there are any differences in sensitivity to nano-chemical insult between the patient and control groups. The results have shown concentration dependent genotoxic effects of TiO2 in both respiratory patient and control groups in the Comet assay and an increasing pattern of cytogenetic damage measured in the micronucleus assay without being statistically significant except when compared with the untreated controls of healthy individuals. Furthermore, modulation of ras p21 expression was investigated. Regardless of TiO2 treatment, only lung cancer and COPD patients expressed measurable ras p21 levels that showed modulation as the result of nanoparticle treatment. Results have suggested that both ZnO and TiO2 nanoparticles can be genotoxic over a range of concentrations without either photoa-ctivation or being cytotoxic.

615.9

Towards Mixed Molecular Layers for Dye-Sensitized Solar Cells : A Photoelectron Spectroscopy Study

Oscarsson, Johan

January 2016

The increasing demand for renewable energy has led to substantial research on different solar cell technologies. The dye-sensitized solar cell (DSC) is a technology utilizing dye molecules for light absorption. Dye molecules are adsorbed to a mesoporous semiconductor surface and after light absorption in the dye, charge separation occurs at this interface. Traditionally, DSCs have used layers of single dye species, but in recent efforts to enhance power conversion efficiency, more complex molecular layers have been designed to increase the light absorption. For example, the most efficient DSCs use a combination of two dye molecules, and such dye co-adsorption is studied in this thesis. A key to highly efficient DSCs is to understand the dye/semiconductor interface from a molecular perspective. One way of gaining this understanding is by using an element specific, surface sensitive technique, such as photoelectron spectroscopy (PES). In this thesis, PES is used to understand new complex dye/semiconductor interfaces. Dyes adsorbed to semiconductor surfaces are analyzed using PES in terms of geometric and electronic surface structure.  The investigations ultimately target the effects of co-adsorbing dyes with other dyes or co-adsorbents. PES shows that Ru dyes can adsorb in mixed configurations to TiO2. Co-adsorption with an organic dye affects the configuration of the Ru dyes. As a consequence, shifts in energy level alignment and increased dye coverage are observed. The dyes are affected at a molecular level in ways beneficial for solar cell performance. This is called collaborative sensitization and is also observed in todays most efficient DSC. Dye molecules are generally sensitive to high temperatures and the substantial decrease in power conversion efficiency after heat-treatment can be understood using PES. Furthermore, comparing two mesoscopic TiO2 morphologies used in DSCs show differences in trap state density in the band gap, explaining the photovoltage difference in DSCs comprising these morphologies. Using mixed molecular layers on NiO results in significant improvements of p-type DSC power conversion efficiency. PES shows that changed adsorption configuration contribute to this effect. This thesis shows that PES studies can be used to obtain insight into functional properties of complex DSC interfaces at a molecular level.

dye-sensitized solar cell

DSC

mesoscopic solar cell

photoelectron spectroscopy

PES

XPS

interface

TiO2

NiO

co-adsorption

co-adsorbent

collaborative sensitization

mixed molecular layers

Ultrafast spectroscopy of charge separation, transport and recombination processes in functional materials for thin-film photovoltaics

Wehrenfennig, Christian

January 2014

Dye-sensitized solar cells (DSSCs) and perovskite solar cells are emerging as promising potential low-cost alternatives to established crystalline silicon photovoltaics. Of the employed functional materials, however, many fundamental optoelectronic properties governing photovoltaic device operation are not sufficiently well understood. This thesis reports on a series of studies using ultrafast THz and photoluminescence spectroscopy on two classes of such materials, providing insight into the dynamics of charge-transport and recombination processes following photoexcitation. For TiO₂-nanotubes, which have been proposed as easy-to-fabricate electron transporters for DSSCs, fast, shallow electron trapping is identified as a limiting factor for efficient charge collection. Trapping lifetimes are found to be about an order of magnitude shorter than in the prevalently employed sintered nanoparticles under similar excitation conditions and trap saturation effects are not observed, even at very high excitation densities. In organo-lead halide perovskites - specifically CH₃NH₃PbI₃ and CH₃NH₃PbI_3-xCl_x, which have only recently emerged as highly efficient absorbers and charge transporters for thin-film solar cells, carrier mobilities and fundamental recombination dynamics are revealed. Extremely low bi-molecular recombination rates at least four orders of magnitude below the prediction of Langevin's model are found as well as relatively high charge-carrier mobilities in comparison to other solution-processable materials. Furthermore a very low influence of trap-mediated recombination channels was observed. Due to a combination of these factors, diffusion lengths reach hundreds of nanometres for CH₃NH₃PbI₃ and several microns for CH₃NH₃PbI_3-xCl_x. These results are shown to hold for both, solution processed and vapour-deposited CH₃NH₃PbI_3-xCl_x and underline the superb suitability of the materials as absorbers in solar cells, even in planar heterojunction architectures. The THz-frequency spectrum of the conductivity of the investigated perovskites is consistent with Drude-like charge transport additionally exhibiting weak signatures of phonon coupling. These coupling effects are also reflected in the luminescence of CH₃NH₃PbI_3-xCl_x, where they are believed to be the cause of the observed homogeneous spectral broadening. Further photoluminescence measurements were performed at temperatures between 4 K and room temperature to study the nature of recombination pathways in the material.

530.4

Génération in situ de dioxyde de titane par réactions d’hydrolysecondensations dans une matrice polymère fondu / In situ synthesis of titanium dioxide by hydrolysis-condensation reactions in molten polypropylene matrix

Bahloul, Walid

20 July 2010

L’objectif de ce travail est de générer in situ des particules de dioxyde de titane dans une matrice polypropylène fondu au cours du procédé d’extrusion. La synthèse est basée sur des réactions d’hydrolyse-condensations d’un alkoxyde de titane (le n-tétrabutoxyde de titane). Une approche en milieu modèle a tout d’abord été développée offrant l’avantage de pouvoir travailler en milieu liquide sans prendre en compte de la viscosité du PP ni des effets de cisaillement. En se basant sur les données cinétiques déterminées en milieu modèle, la génération de ces particules de dioxyde titane a été ensuite transposée et modélisée dans le milieu polymère de masse molaire plus élevée. Les analyses chimique, structurale et morphologique ont permis de mettre au point l’élaboration in situ de nanocomposites PP/TiO2 présentant unestructure fractale avec des propriétés viscoélastiques particulières. Enfin l’étude des propriétés bactérienne de ce nanocomposite a mis en avant son pouvoir bactéricide (6Log) pour un taux de charge de 9 % massique. / Polypropylene/Titanium dioxide (PP/TiO2) nanocomposites were prepared from an original method based on the hydrolysis-condensation reactions of titanium alkoxide inorganic precursor premixed with PP under molten conditions. The synthesis is based on sol-gel method without solvent through extrusion process. A second treatment in hot water was applied in order to improve final conversion degree. First, hydrolysis-condensation reactions of titanium n-butoxide precursor were studied in model medium. Based on a kinetic equation carried out in the model medium, then the synthesis of titanium dioxide particles was transposed and modelled in polypropylene medium with high molar mass. Chemical, structural and morphological analyses highlight the in situ synthesis of bactericides PP/TiO2 nanocomposites andpresenting a particular morphological and rheological behaviour.

Polypropylène

Dioxyde de titane

Génération in situ

Hydrolyse-condensation

Sol-gel

Nanocomposites PP/TiO2

Extrusion réactive

Propriétés antibactériennes

Polypropylene

Titanium dioxide

Hydrolysis-condensation

Nanocomposites

Antibacterial

Reactive extrusion

547

Investigating the Electron Transport and Light Scattering Enhancement in Radial Core-Shell Metal-Metal Oxide Novel 3D Nanoarchitectures for Dye Sensitized Solar Cells

Sahu, Gayatri

18 May 2012

Dye-sensitized solar cells (DSSCs) have attained considerable attention during the last decade because of the potential of becoming a low cost alternative to silicon based solar cells. Electron transport is one of the prominent processes in the cell and it is further a complex process because the transport medium is a mesoporous film. The gaps in the pores are completely filled by an electrolyte with high ionic strength, resulting in electron-ion interactions. Therefore, the electron transport in these so called state-of-the-art systems has a practical limit because of the low electron diffusion coefficient (Dn) in this mesoporous film photoanode. This work focuses on the influence of the advanced core-shell nanoarchitecture geometry on electron transport and also on the influence of electron-ion interactions. In order to achieve the proposed goals, DSSCs based on ordered, highly aligned, 3D radial core-shell Au-TiO2 hybrid nanowire arrays were fabricated, using three different approaches. J-V, IPCE, and EIS characteristics were studied. The efficiency, light scattering and charge transport properties of the core-shell nanowire based devices were compared to TiO2 nanotube as well as TiO2 mesoporous film based DSSCs. The Au nanowires inside the crystalline TiO2 anatase nanoshell provided a direct conduction path from the TiO2 shell to the TCO substrate and improved transport of electrons between the TiO2 and the TCO. The optical effects were studied by IPCE measurement which demonstrated that Au-TiO2 nanowires showed an improved light harvesting efficiency, including at longer wavelengths where the sensitizer has weak absorption. The metal nanostructures could enhance the absorption in DSSCs by either scattering light enabling a longer optical path-length, localized surface plasmon resonance (LSPR) or by near-field coupling between the surface plasmon polariton (SPP) and the dye excited state. Rapid, radial electron collection is of practical significance because it should allow alternate redox shuttles that show relatively fast electron-interception dynamics to be utilized without significant sacrifice of photocurrent. A combination of improved electron transport and enhanced light harvesting capability make Au-TiO2 core-shell nanowire arrays a promising photoanode nanoarchitecture for improving photovoltaic efficiency while minimizing costs by allowing thinner devices that use less material in their construction.

Inorganic Chemistry

Materials Chemistry