Toxicity of double-walled carbon nanotubes to algae, macro-invertebrates and fish

02 July 2015

PhD. (Chemistry) / This project assessed the toxicity of double-walled carbon nanotubes to three aquatic organisms belonging to different trophic levels, namely Pseudokirchneriella subcapitata (algae), Daphnia pulex (macro-invertebrate) and Poecilia reticulata (fish). Prior to the toxicity testing, the dry DWCNTs were characterised using scanning electron microscopy, transmission electron microscopy, energy dispersive X-ray spectroscopy and Raman spectroscopy. Dynamic light scattering was used to characterise DWCNT suspensions. Natural water parameters such as increased ionic strength (Ca2+ and Na+) and increased humic acid affected the agglomeration potential of DWCNTs in aquatic medium. Increased ionic strength increased the agglomeration of DWCNTs while humic acid decreased agglomeration. The study explored the lethal/effective concentrations and sublethal effects of DWCNTs on the three organisms. The LC50/EC50 of DWCNTs for the three organisms differed in order of magnitude with D. pulex being the most sensitive and P. reticulata being the least sensitive. The LC50 for D. pulex was 2.81 and 4.45 mg/L for pristine and oxidised DWCNTs, respectively. Pseudokirchneriella subcapitata had an average EC50 of 10.01 mg/L and 10.93 mg/L for pristine and oxidised DWCNTs, respectively. Poecilia reticulata had an LC50 of 113.64 mg/L and 214.0 mg/L for pristine and oxidised DWCNTs, respectively. Exploring the effects of natural water parameters such as humic acid and ionic strength revealed that the acute toxicity of DWCNTs to D. pulex and P. reticulata was increased with increasing humic acid concentrations in exposure media, but increased ionic strength decreased the toxicity of both pristine and oxidised DWCNTs. However, these water parameters all decreased the toxicity of DWCNTs to P. subcapitata. The acute toxicity of DWCNTs was found to be directly linked to their agglomeration state in aquatic systems. Humic acid decreased the hydrodynamic sizes of DWCNT agglomerates making the engineered nanomatrials (ENMs) more available to the organisms while the cations increased the hydrodynamic sizes of DWCNT agglomerates, thereby reducing the probability of interactions with organisms. Time-based survival plots revealed that for P. reticulata and P. subcapitata, there were steady mortality/growth inhibitions throughout the duration of the exposures. For D. pulex, however, the plots revealed that there was a high initial die-off, whereafter mortalities proceeded at different rates. An assessment of whether DWCNTs cause oxidative stress in the three organisms revealed that DWCNTs caused significantly high oxidative stress in D. pulex and P. reticulata but not in P. subcapitata. In D. pulex and P. reticulata, DWCNTs were found to also cause DNA damage. The sublethal toxicity of DWCNTs was affected differently by the humic acid and increased cation concentration in exposure experiments. The sublethal effects were linked to the mode of interaction between DWCNTs and organisms. In P. subcapitata, the interaction was mainly physical with DWCNTs entrapping the algal cells in agglomerates and depriving the algal cells of light for normal photosynthesis to take place. For the other two organisms, the interaction was through intestinal cells as the organisms ingested DWCNTs and through accumulation of nanotubes on the exterior or organisms. The intestinal cell/DWCNT interaction resulted in the excessive generation of reactive oxygen species (ROS) and led to the death of the organism. Humic acid induced the highest antioxidant responses in both D. pulex and P. reticulata and this led to increased DNA damage in both organisms. Increased ionic strengths induced increased antioxidant responses at some DWCNT concentrations but the DNA damage was not significantly increased. These results suggested that with humic acid, the ROS production was excessive and sustained and had an effect on the DNA. The ROS production in increased ionic strengths was not excessive and was not prolonged, reducing their impact on DNA. The use of three organisms to assess the toxicity of DWCNTs provided comprehensive information on the potential effects of these ENMs in the aquatic food chain. Moreover, a multi-tier approach provided information on the potential effect of DWCNTs on populations at sublethal concentrations.

Carbon nanotubes - Toxicology

Aquatic organisms - Effect of metals on

Fabrication et intégration dans un module assemblé d'une jauge de déformation et d'humidité à base de nanotubes de carbone

Landry, Simon

January 2017

La technique puce retournée pour l’encapsulation des puces est largement utilisée dans l’industrie, mais présente de nombreux défis. Cette technique requiert que les matériaux utilisés subissent de hautes températures (250°C). Or, le silicium et le substrat organique ont des coefficients d’expansion thermique (CET) très différents. Donc, ces températures et la différence de CET induisent des contraintes sur la puce. Ces contraintes affectent les performances électriques de la puce et peuvent provoquer la fissuration de celle-ci. L’humidité à l’intérieur du module s’ajoute aux problèmes. Elle corrode les interconnexions puis facilite la formation de trous dans l’époxy utilisé pour augmenter la cohésion mécanique entre la puce et le substrat. Jusqu’à maintenant des jauges de déformations sur silicium ont été réalisées. Bien que les facteurs de jauges obtenus soient grands (100), cette technique basée sur la théorie des semi-conducteurs nécessite que la surface dédiée à la circuiterie soit remplacée par la jauge. Actuellement, aucune technique ne permet de mesurer efficacement les déformations sur la surface d’une puce sans modifier sa circuiterie. Ainsi, l’objectif est de développer une jauge de déformation et d’humidité portable constituée de nanotubes de carbone. Cette jauge sera positionnée directement sur la couche de polyimide, elle-même située sur la circuiterie. Les propriétés piézorésistives des nanotubes ainsi que leurs dimensions sont des atouts pour la conception de ces jauges micrométriques. Globalement, le projet se sépare en trois volets : étude et optimisation des films de nanotubes, fabrication de capteurs prototypes puis intégration des capteurs dans le module. Le premier volet sert à déterminer la méthode optimale de dépôt des nanotubes et le type de nanotubes préférables. La fabrication de capteurs prototypes permet de définir un procédé de microfabrication et de calibrer en déformation, température et humidité.

Jauge

Déformation

Humidité

Nanotubes de carbone

Encapsulation des puces

Effets de traitements post-synthèses sur la surface de nanotubes de carbone mono et multi-parois étudiés par la physisorption de gaz / Effects of post-synthesis treatments on the surfaces of single-and multi-wall carbon nanotubes studied by gas physical adsorption

Le, Thi Ngoc Ha

29 June 2009

Les recherches de cette thèse avaient pour but la compréhension de l’influence sur les parois de nanotubes de carbone de divers traitements post-synthèses : purification, recuit, découpage ultrasonique et fonctionnalisation. Si ce travail porte principalement sur la physisorption de gaz rares, plusieurs autres techniques d’études complémentaires ont également été utilisées telles que la microscopie électronique, l’analyse thermogravimétrique et la diffraction des rayons X. Une méthode systématique a été proposée pour déterminer le début et la fin des marches, souvent mal définies, qui sont contenues dans les isothermes représentant l’adsorption de gaz sur des tubes mono-parois. Nos résultats s'intéressent en particulier (i) à l'estimation du taux d’ouverture des tubes suivant certains des traitements précités, (ii) à l’applicabilité de la méthode BET au-delà de ses limites habituelles et (iii) dans le cas d'un traitement de fonctionnalisation, à la sélectivité des procédés de greffage sur les surfaces des nanotubes par rapport à celles correspondantes à d’autres espèces carbonées présentes dans un même échantillon. / The aim of this study was to understand the influence of various post-synthesis treatments on carbon nanotube surfaces: purification, annealing, ultrasonic cutting, and functionalization. This work deals mainly with rare gas physisorption, but other complementary techniques have also been used such as electron microscopy, thermogravimetric analysis and X-ray diffraction. A systematic approach has been proposed to determine the beginning and the end of the steps (which are usually not well-defined) on the isotherms corresponding to the gas adsorption on single-wall nanotubes. Our results focus in particular on (i) the estimation of the tube opening rate after several of the above mentioned treatments (ii) the validity of the BET method beyond its usual limits and (iii) in the case of functionalization, the selectivity of the grafting process on the carbon nanotube surfaces as opposed to that on the other carbon species present in a sample.

Nanotubes de carbone

Physisorption

Traitement de post-synthèse

Optical spectroscopy of bound excitonic states in single walled carbon nanotubes / É tude spectroscopique des états excitoniques liés dans les nanotubes de carbones monoparois

Morim Santos, Silvia

16 May 2012

Dans ce manuscrit nous décrivons des études originales sur les propriétés photophysiques des nanotubes de carbone monoparois réalisées à l'échelle de la molécule unique. Nous nous sommes concentrés sur deux problématiques : l'effet du remplissage des nanotubes par de l'eau sur leurs propriétés de photoluminescence (PL) et la création de complexes multi-excitoniques en régime de forte excitation laser. Dans ce but nous avons utilisé une combinaison de microscopie, de spectroscopie et de mesures de déclin de PL. Nos résultats montrent pour des nanotubes de différents diamètres un décalage vers le rouge des énergies d'émission pour les nanotubes remplis d'eau. De plus, des déclins de PL biexponentiels sont obtenus pour des nanotubes individuels (6,4) vides et remplis d'eau. Les temps de déclin caractéristiques de ces deux espèces de nanotubes sont distincts, avec une réduction de la composante courte pour les nanotubes remplis. Ces résultats sont expliqués par une augmentation de la constante diélectrique dans les nanotubes remplis d'eau. Notre résultat le plus conséquent a été l'observation de la génération de trions dans des nanotubes non dopés en utilisant des moyen tout optiques. L'émission du trion apparaît dans les spectres de PL comme une bande latérale décalée vers le rouge. Basé sur nos observations expérimentales, nous proposons le modèle de génération du trion suivant lequel dans un régime multiexcitonique les interactions d'annihilation exciton-exciton créent des porteurs de charge qui sont piégés dans les fluctuations de potentiel électrostatique induites par les inhomogénéités de l'environnement. L'absorption subséquente d'un photon amène à la formation d'un trion localisé sur les charges piégées. / In this dissertation we report on original experimental investigations of the photophysical properties of individual single-walled carbon nanotubes (SWCNTs) at the single molecule level. We focused on two problems: the effect of water-filling nanotubes on their photoluminescence (PL) properties and generation of multi-excitonic complexes in regimes of strong laser excitation. To do so we used a combination of microscopy, PL spectroscopy and PL time decay measurements. Our results show, for different nanotube diameters, a red-shift of the PL emission energy for water-filled nanotubes. Furthermore, biexponential PL time decay behaviors are obtained for individual water-filled and empty (6,4) SWCNTs. The characteristic decay times for both species of nanotubes are distinct, with a reduction of the short component in water-filled SWCNTs. These results are explained by an increase of the dielectric constant for water-filled nanotubes. Our most consequential experimental result was the observation of all optical trion generation in undoped nanotubes. Trion emission appears in the PL spectrum as a red-shifted sideband. Based on our experimental observations, we propose a trion generation model according to which, at a multiexcitonic regime, exciton-exciton annihilation interactions create charge carriers that are transiently trapped at electrostatic potential fluctuations induced by the inhomogeneities of the environment. Subsequent photon absorption leads to trion formation localized at the trapped carriers.

Nanotubes de carbones mono-parois

Microscopie de luminescence

Nanotubes vides et remplis d'eau

Trions

Expériences de molécule unique

Single-walled carbon nanotubes

Photoluminescence microscopy

Empty and water-filled nanotubes

Trions

Single-molecule experiments

A novel classical synthetic approach to carbon nanotubes and their functionalized derivatives

Wiredu, Bernard

January 1900

Doctor of Philosophy / Department of Chemistry / Duy H. Hua / Carbon nanotubes are allotropes of carbon comprising of one or more grapheme sheets seamlessly joined together to form a cylinder. They are classified as single-walled carbon nanotubes (SWNTs) or multi-walled carbon nanotubes (MWNTs). They have potential applications ranging from conductive and high reinforcement material components, nano interconnection in electronic devices to drug delivery in biological systems. Current methods of production are high temperature arc-discharge, laser ablation of graphitic materials and chemical vapor deposition. These methods give tubes that are impure and highly heterogeneous in length, diameter and chirality thus leading to mixture metallic and semiconducting tubes. Effective application of such carbon nanotubes requires cumbersome, harsh and expensive purification and sorting into like forms. Such treatments usually compromised the structural integrity of the tubes and hence their mechanical and electrical properties. Also pristine carbon nanotubes are insoluble in most solvents. Solubility in basic organic solvents is crucial prior to their application, which requires some level of chemical manipulation or functionalization on the tubes. Currently methods of functionalization are unpredictable and limited to few oxidation reactions. A novel rational synthetic chemical approach to [12, 12] arm-chair carbon nano tube with pre-defined diameter and length has been explored utilizing cheap and simple organic building blocks and results achieved so far have been presented in this dissertation. Two approaches were employed to form the carbon-rich beltene (32) before its final conversion to the target single-walled carbon nanotube (SWNT) 1. A survey on carbon nanotubes and their related structures including their potential applications and properties are presented in chapter 1. In the second chapter an iron template-assisted olefin metathesis via a ferrocene intermediate served as an anchor for an effective cyclization. In chapter 3, an un-assisted olefin metathesis pathway was explored. Both approaches use a series of benzyl halide carbonylation coupling and Diels-Alder reactions to synthesize some of the key intermediates. The protocol presented in this dissertation may be used to produce functionalized carbon nanotubes with predefined length and diameter tailored for specific applications to be produced in kilogram scale for the first time since its discovery in 1991. Such an approach is expected to address most if not all of the problems associated with the traditional methods of producing carbon nanotubes.

Carbon nanotubes

Single-walled carbon nanotubes

Step-wise synthesis of carbon nanotubes

Template-assisted olefin materials

Triphenylophane

Chemistry, General (0485)

Chemistry, Organic (0490)

Dynamic electrical transport in carbon nanotubes and nanodiamond films

Chimowa, George

January 2014

A thesis submitted to the Faculty of Science, University of the Witwatersrand, Johannesburg, in fulfilment of the requirements for the degree of Doctor of Philosophy. / A comprehensive experimental study on alternating current (AC) electrical transport in the three forms of carbon nanotubes (CNTs) and nanodiamond films is presented. It is termed dynamic electrical transport to differentiate it from direct current measurements, which may be referred as static transport. The results and analysis are based on the scattering parameter measurements of a few horizontally aligned single, double, multi-walled carbon nanotubes and nanodiamond films. Which were measured in the frequency range 10 MHz to 65 GHz, at room and cryogenic temperatures using a vector network analyser. The work is motivated by the fact that AC transport in 1D systems has not been fully studied and is not well understood. From direct current measurements, it is known that one dimensional (1D) electrical transport is very different from its two or three dimensional counterpart. This is because adding an electron to a 1D system tends to affect the whole system in ways which to date cannot be fully explained theoretically. CNTs present an ideal platform to study the AC or dynamic transport behaviour of 1D systems because of the high mobility and electrical conductivity at nano-scale. Therefore from the AC complex impedance and conductance, this work demonstrates quantum effects of collectively excited strongly interacting electrons (Luttinger Liquid), which had been predicted theoretically but not observed experimentally using this technique. Ballistic transport at room temperature is also demonstrated by setting the stimulus frequency higher than the scattering rate in the CNTs. A crossover from capacitive to inductive behaviour in the imaginary component of impedance has been shown by improving the CNT-electrode coupling. Furthermore the effect of metal contacts on microwave/ radio frequency transmission is also demonstrated. The results are consolidated by RF simulations, as strong conclusions are drawn. Studies on the dynamic transport in nanodiamond films revealed a crossover from the insulating to semi-metallic regime by nitrogen incorporation. The crossover is explained by considering the changes of the grain boundary morphology. This work shows that AC transport in polycrystalline nanodiamond films is similar to DC transport.

Nanostructured materials.

Nanostructures.

Nanotubes, Carbon content.

Carbon.

Synthesis of carbon nanofibers and their subsequent use as catalyst supports for Fischer-Tropsch synthesis

Phaahlamohlaka, Tumelo Nathaniel

07 July 2014

In this study the synthesis and use of carbon nanofibers (CNFs) as catalysts supports for Fischer Tropsch synthesis is reported. The synthesis of carbon nanofibers with two distinct morphologies was optimized based on the reports in the literature that the straight (SCNF) and helical (CCNF) carbon nanofibers grow on Cu catalysts with different particle sizes. To selectively grow CNFs with a single morphology Cu catalysts were designed using different synthesis procedures (by using unsupported, coated and silica supported catalysts). The prepared copper oxide (CuO) nanoparticles were characterized by techniques such as TEM, XRD and nitrous oxide chemisorption. These techniques showed that the unsupported and coated CuO catalyst precursors has large particle sizes (range 100-300 nm) and thus had low Cu atomic surface area, while the supported CuO catalysts displayed low particles sizes in the nanoscale regime (<20 nm) and hence had high atomic surface area. Preparation of CNFs was carried out 300 using acetylene (C2H2) gas as the carbon source. Cu catalysts with large particle sizes resulted in straight CNFs and the small supported Cu nanoparticles grew helical CNFs because of the change in the nanoparticle surface energy during adsorption of the acetylene gas and the silica (SiO2) support effects that limited Cu nanoparticles from sintering (i.e. final particles size 60 nm). Soxhlet extraction proved to be an invaluable step in removing adsorbed polycyclic aromatic hydrocarbons. Because of the low thermal stability of these CNFs the materials were then annealed at higher temperatures ranging from 500-1400 in an inert environment (passing N2 gas). The helical CNFs snapped under high temperature annealing ( 900 ) resulting in shorter lengths in comparison to the straight CNFs. BET analysis of the annealed CNFs indicated that the CNFs annealed at 500 and 900 have increased surface area and have a mesoporous pore structure with the surface area ranging from 200-350 m2/g. Raman and Fourier transform IR spectroscopy indicated that the CNFs annealed at 500 and 900 , (which were the main material of interest because of their high surface area and thermal stability) had different hybridized carbon content. CNFs annealed at 500 contained both sp2 and sp3 hybridized carbon while annealing the CNFs at 900 resulted in a complete rehybridization of the carbon content to sp2. The carbon sp3 content in the CNFs annealed at 500 therefore implied that CNFs annealed at this temperature are more defective in comparison to the CNFs annealed at 900 . Since it is well known that material functionalities are affected by the amount of defects present inside the different CNFs were then applied as catalyst supports for Fischer Tropsch synthesis (FTS) to compare the support effects on cobalt active sites. The CNF surfaces were first modified by functionalization using concentrated HNO3 solution. The preparation of the catalyst systems was performed by a simple HDP method using urea. The CNFs and the FT catalysts were characterized using different techniques such as XRD, TEM, BET, TPR and Raman spectroscopy. Reactor studies performed at 220 (P = 8 bar, GHSV= 1200 mL.h-1. ) showed the catalysts had activities with CO conversion ranging from 25-45%. It was observed that catalysts supported on CNFs annealed at 500 displayed higher average activities of about 15% (based on the CO conversions) in relation to the catalysts supported on CNFs annealed at 900 . Catalysts showed minimal water gas shift reaction and high methane selectivity (i.e. 20-30%) which can be attributed to the small Co crystallite sizes and low pressure reaction conditions.

Fischer-Tropsch process.

Catalysts.

Nanotubes.

Carbon.

Synthesis.

CVD synthesis of nitrogen doped carbon nanotubes using iron pentacarbonyl as catalyst

Ghadimi, Nafise

24 February 2012

M.Sc., Faculty of Science, University of the Witwatersrand, 2011 / In this dissertation, the synthesis of nitrogen doped carbon nanotubes (N-CNTs) was performed successfully, using a floating catalyst chemical vapour deposition (CVD) method. Fe(CO)5 was utilized as the catalyst and acetonitrile and toluene as nitrogen and carbon sources respectively. Two different procedures were used to add reagents to the reactor: an injection method and a bubbling method. The effect of nitrogen concentration and physical parameters such as reaction temperature, gas flow rate on the morphology, crystallinity and thermal stability of the tubes was studied. The synthesized materials were characterized by means of Raman spectroscopy, TGA and TEM analyses. The presence of nitrogen was confirmed by the presence of the bamboo formations in the tubes by TEM. A comparison of the data from the numerous reactions revealed that N-CNTs can be made from Fe(CO)5 and acetonitrile. Further the main conclusions achieved using the injection method were: i) the maximum number of tubes with bamboo structure were made using on acetonitrile concentration of 15%, ii) The best growth temperature to make N-CNTs was 850 oC, iii) An increase in acetonitrile concentration decreased the yield of NCNTs and iv) Tubes with the narrowest outer diameters were made using an acetonitrile concentration of 15%.

Nanotubes

Nanostructures

Metal ions

Nanostructured materials

Nanochemistry

Titania derived nanotubes and nanoparticles : catalyst supports in hydrogenation, oxidation and esterification reactions

Sikhwivhilu, Lucky Mashudu

20 January 2009

Nanotubular titanates were synthesized by a simple methodology using a commercial TiO2 (Degussa P25 containing anatase and rutile phases) and a base (KOH) solution. Prior to the removal of KOH, the samples of TiO2 were aged for three different time intervals (0, 2 days, 61 days). The freshly prepared synthetic samples were characterized for their structural and morphological properties by BET, XRD, Raman, TEM, HRTEM, EDX and SEM. Both TEM and SEM analysis revealed that ageing time influenced the tubular structure and morphology of the new materials. Raman and surface analysis data also showed that ageing time affected both the structural and surface properties of TiO2. The XRD results showed that the crystallinity of the TiO2 decreased with increasing ageing time. Energy dispersive Xray spectroscopy (EDX) showed that the tubes derived from TiO2 are comprised of potassium, titanium and oxygen. Catalysts A, B and C were prepared by the addition of 1 wt% Pd (wet impregnation) to the titanate formed after ageing of the TiO2 in KOH for 0, 2 and 61 days, respectively. The catalysts were tested for the vapour phase hydrogenation of phenol in a fixed-bed micro reactor within the temperature range of 165 to 300oC under atmospheric pressure. Of the three catalysts, catalyst B showed the best activity (conversion 97%) and total selectivity to cyclohexanone (99%). In contrast, catalyst C, which showed a moderate activity favoured selectivity to cyclohexanol. These results are attributed to differences in surface morphologies between the two catalysts B and C, associated with the surface area and a change in the surface acid-base properties. Catalyst B also showed a higher resistance towards deactivation and maintained a higher total selectivity to cyclohexanone than did catalyst C. A hydrothermal treatment of NaOH and TiO2 was employed to prepare two materials, TiO2-B and TiO2-C with relatively small crystallite size and large specific surface area. The hydrogenation of phenol was used to evaluate the activity of the catalysts Pd/TiO2-B and Pd/TiO2-C. The reaction proceeds in a single step and involves the formation of a partially hydrogenated product, namely cyclohexanone. The larger surface area catalyst (Pd/TiO2-C, 89 m2/g) showed better activity and selectivity to cyclohexanone than its counterpart (Pd/TiO2-B, 45 m2/g). The catalyst activity showed significant dependency on the surface area whereas the selectivity was greatly influenced by surface basicity. Titania derived nanotubes synthesized by treating P25 Degussa TiO2 with a concentrated KOH solution and aged for 2 days was used as a catalyst support for the hydrogenation of o-chloronitrobenzene (O-CNB) with Pd as the active phase. The vapour-phase hydrogenation of O-CNB was carried out in ethanol at 250 oC and atmospheric pressure over a Pd/TiO2 derived nanotube catalyst (Pd/TiO2-M). Pd/TiO2-M gave complete conversion (100%) of O-CNB with a selectivity to orthochloroaniline (O-CAN) of 86 %. The stability of the Pd/TiO2 catalyst was tested over 5 hours during which time the conversion slowly dropped to 80 % (selectivity 93 %) due to poisoning. TPR analysis revealed the existence of a strong palladium-support interaction and this was found to be crucial to the overall activity of the catalyst. It has been found that gold supported on potassium titanate, KTiO2(OH) can, under some circumstances, exhibit a superior performance for the oxidation of carbon monoxide, relative to that obtained with titania as a support. It appears that the dispersions of gold on the two types of support are sufficiently similar that other factors are responsible for the improved activity noted. It may be that the higher basic character and detailed structural features of the titanate surface play a role. The effect of the addition of alkali metal ions on the anatase to rutile transformation of titanium dioxide (P25 Degussa) was investigated using X-ray diffraction, Raman spectroscopy, and surface area measurements. Both Li and Cs ions accelerated the anatase to rutile transformation whereas Na and K ions did not show any effect. Furthermore, the effect was more pronounced after addition of the Li ions so that the transformation temperature dramatically decreased from ~800 oC for commercial TiO2 to ~600 oC. The surface area of the TiO2 material decreased with sintering due to the increase in crystalline size. Moreover, the acceleration of the transformation occurred at lower temperatures and at higher Li content. Mesoporous nanocrystalline TiO2 (HSA TiO2) was prepared by hydrothermal treatment of TiO2 with NaOH. The material was very amorphous and underwent the phase transformation from amorphous to anatase phase and subsequently from anatase to rutile phase with sintering. The anatase to rutile transformation was delayed after doping and grain growth was inhibited. After sintering at 800 oC the material (HSA TiO2) still contained a significant amount of the anatase phase. The complete transformation only occurred at ~1000 oC. The esterification of benzoic acid and butyric acid with propanol over alkali metal ions supported on TiO2 was investigated. K/TiO2-D showed the highest conversion for both benzoic acid and butyric acid. The selectivity to propylbenzoate and propylbutyrate was influenced by the basic nature of the catalysts. Butyric acid was found to be more reactive than benzoic acid. The difference in reactivity was explained in terms of steric and inductive effects. The differences in boiling points and pH values were also considered.

Titania nanotubes

titanate

co-oxidation

esterification

Desenvolvimento e caracterização de sensores eletroquímicos baseados em nanotubos de carbono alinhados com DNA para a detecção de bisfenol A / Development and characterization electrochemical sensors based aligned single-walled carbon nanotubes for electrochemical bisphenol-A determination

Silva, Tiago Augusto da

20 September 2013

Neste trabalho foram imobilizados nanotubos de carbono de parede simples sobre um eletrodo de ouro policristalino gerando uma camada de nanotubos alinhados verticalmente na superfície do eletrodo. Para isto, foi utilizado um fragmento de DNA (ssDNA tiol-terminado (5-HS-TGG-GGT-TTA-TGG-AAA-TTGGAA-3)) que foi posicionado ao redor do nanotubo de carbono com o procedimento seguinte: 1,0 mg SWCNT funcionalizado foi misturado com 1,0 mL de uma solução de ssDNA de 1,0 &micro;mol L-1, e o ssDNA foi preparado em 0,1 molL-1 de PBS contendo cloreto de sódio a 10% (v / v). Em seguida, a mistura foi sonicada usando uma sonda de ultra-som por 45 min e depois centrifugada a 10000 rpm por 30 min. Finalmente, um eletrodo de Au previamente limpo foi imerso na solução de sobrenadante e monocamadas auto-organizadas (SAM), que consistem de ssDNA/SWCNT foram formadas durante 24 h numa sala refrigerada a 4 &deg;C. As características morfológicas dos eletrodos foram determinadas por microscopia de força atômica, observando-se o alinhamento vertical, que alterou a rugosidade do eletrodo de 1,95 nm para 47,5 nm, com a altura média dos SWCNTs de 260,3 nm, com um desvio padrão relativo de 19,9%. O comportamento eletroquímico do eletrodo de ouro modificado com o hibrido ssDNA/SWCNT foi caracterizado utilizando voltametria cíclica em meio de Na2SO4 0,1 mol L-1 contendo K3Fe(CN)6 5,0 mmol L-1, com velocidade de varredura de potencial de 50 mVs-1. Observou-se que a reversibilidade do par redox Fe(CN)63-/Fe(CN)64- é maior para o eletrodo modificado com ssDNA/SWCNT (&Delta;Epico= 80 mV) quando comparado ao eletrodo de Au (&Delta;Epico = 115 mV). A modificação proporcionou uma resposta mais eletrocatalítica com um deslocamento de 43 mV para valores menos positivos do potencial de oxidação do Fe(CN)63-. A oxidação no eletrodo de Au/ssDNA/SWCNTs ocorre em +417 mV e no eletrodo de Au em +460 mV. Este aumento de reversibilidade foi quantificado por espectroscopia eletroquímica de impedância faradaica, onde se encontrou os valores de constantes de velocidade de 7.56 &times; 10-5 cm s-1 para o eletrodo modificado e apenas 3,36 &times; 10-5 cm s-1 para o de ouro puro. O efeito da modificação da superfície Au com o nanohíbrido ssDNA / SWCNT na oxidação do bisfenol-A (BPA) foi avaliado em Na2SO4 0,1 mol L-1, pH 6,0, contendo 100 &micro;mol L-1 de BPA por voltametria cíclica a 50 mV s-1. Observou-se um processo de oxidação com um pico voltamétrico anódico num valor de potencial de 510 mV. Este processo de oxidação está relacionado com a eletro-oxidação de BPA para íons fenoxeno. O processo ocorreu em um potencial menos positivo do que o valor observado para o eletrodo de Au não modificado, ou seja 720 mV. Além disso, o processo oxidativo referente à superfície modificada mostrou-se mais catalítico, proporcionando um aumento do pico de oxidação de 163%. <br /> Para a metodologia analítica, procurou-se se maximizar o sinal analítico da técnica de voltametria de pulso diferencial, DPV, assim a resposta para o eletrodo de Au/ssDNA/SWCNT foi estudada em relação ao pH, salto de potenciais e a amplitude de pulso. Os valores ótimos encontrados foram 6,0, 2 mV e 50 mV, respectivamente. Nestas condições o eletrodo de Au/ssDNA/SWCNT foi aplicado para a determinação de BPA em uma solução de Na2SO4 0,1 mol L-1, pH 6,0. A resposta analítica tem um comportamento linear na faixa entre 1,0 - 4,5 &micro;mol L-1, de acordo com a seguinte equação: I (&micro;A) = 0.019 (&micro;A) + 5.82 (&micro;A/ &micro;molL-1) [BPA], com um coeficiente de correlação de 0,996 (n = 10) e um limite de detecção (LOD) de 11,0 nmol L-1 (2,51 &micro;g L-1) determinado de acordo com as recomendações da IUPAC. O valor obtido é menor que aqueles disponíveis na literatura. / In the present work, single-walled carbon nanotubes (SWCNT) were immobilized over top a polycrystalline gold electrode. This immobilization assembled a layer of vertically aligned nanotubes on the electrode surface. For this purpose, it was used a DNA probe (ssDNA thiolated (HS-5-TGG-TTA-TGG-GGT-AAA-TTGGAA-3)) that has been used to wrap the carbon nanotube as the following procedure: 1.0 mg of functionalized SWCNT was mixed with 1.0 mL of 1.0 &micro;mol L-1 of a ssDNA solution prepared in 0.1 mol L-1 of PBS containing 10% (v/v) of sodium chloride. Next, the mixture was sonicated using an ultrasonic horn probe and then centrifuged at 10000 rpm; each process took 45 min. Finally, a previously cleaned Au electrode was immersed in the supernatant solution. Self-assembled monolayers (SAMs) consisting of ssDNA/SWCNT were formed after 24 h in a refrigerated room at 4 &deg;C. The morphological characteristics of the electrodes were determined using atomic force microscopy. It was observed that the vertical alignment increased the electrode surface roughness of 1.95 nm to 47.5 nm. The average height of the SWCNT was calculated at 260.3 nm, with a relative standard deviation of 19.9%. The electrochemical behavior of gold electrode modified with the ssDNA/SWCNT hybrid was characterized using cyclic voltammetry (CV) in 0.1 mol L-1 of Na2SO4 containing 5.0 mmol L-1 of [K3Fe(CN)6], with a scan rate of 50 mVs-1. It was observed that the reversibility of the redox couple Fe(CN)63-/Fe(CN)64- decreased using the electrode modified with ssDNA/SWCNT (&Delta;Epeak = 80 mV), when compared with the Au electrode (&Delta;Epeak = 115 mV). The modification provided an electrocatalytic response with a shift of 43 mV to less positive values on the Fe(CN)63- oxidation potential value. The oxidation on the Au/ssDNA/SWCNT electrode occurs at +417 mV and the Au electrode at +460 mV. This improvement on the reversibility was quantified using the electrochemical impedance spectroscopy, in which it was observed an apparent constant rate at 7.56 x 10-5 cm s-1 for the modified electrode and 3.36 x 10-5 cm s-1 for pure gold. The effect of the modification of the Au surface with the nanohybrid ssDNA/SWCNT on the bisphenol A (BPA) oxidation was evaluated 0.1 mol L-1 of Na2SO4 (pH 6.0) containing 100 &micro;mol L-1 of BPA. The system was evaluated using CV at 50 mV s-1. The CV experiments showed an oxidation process with an anodic peak potential at 510 mV. This oxidation process is attributed to the electro-oxidation of the BPA forming the fenoxene ions. The process occurred at a less positive potential value when compared with the unmodified Au electrode, i.e. 720 mV. Moreover, surface modified with the nanohybrid presented more catalytic providing an increase of 163% on the oxidation current peak. For the analytical methodology, the analytical signal was maximized. For this, the differential pulse voltammetry (DPV) parameters such as: pulse amplitude and step potential and pH were optimized. The optimum values found were pH at 6.0, pulse amplitude at 50 mV and step potential at 2 mV. In these conditions, the Au/ssDNA/SWCNT electrode was applied for the BPA determination in 0.1 mol L-1 of Na2SO4. The analytical response showed a linear relationship in a range from 1.0 to 4.5 &micro;mol L-1, in accordance with the following equation: I (&micro;A) = 0.019 (&micro;A) + 5.82 (&micro;A / &micro;mol L-1) [BPA ], with a correlation coefficient of 0.996 (n = 10). The limit of detection (LOD) of 11.0 nmol L-1 (2.51 &micro;g L-1) was determined in accordance with the IUPAC recommendations. The obtained value is smaller than those available in the literature.

bisfenol-A

bisphenol-A

DNA

DNA

nanotubes

nanotubos