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Explorations of Functionalized Gold Nanoparticle Surface Chemistry for Laser Desorption Ionization Mass Spectrometry ApplicationsGomez Hernandez, Mario 1980- 02 October 2013 (has links)
Functionalized nanoparticles provide a wide range of potential applications for Biological Mass Spectrometry (MS). Particularly, we have studied the effects of chromophore activity on the performance of gold nanoparticles (AuNPs) capped with substituted azo (-N=N-) dyes for analyte ion production in Laser Desorption Ionization Mass Spectrometry (LDI-MS) conditions. A series of aromatic thiol compounds were used as Self-Assembled Monolayers (SAM) to functionalize the surface of the AuNPs. Results indicate that AuNPs functionalized with molecules having an active azo chromophore provide enhanced analyte ion yields than the nanoparticles capped with the hydrazino analogs or simple substituted aromatic thiols.
We have also conducted experiments using the azo SAM molecules on 2, 5, 20, 30, and 50 nm AuNPs exploring the changes of Relative Ion Yield (RIY) with increased AuNP diameters. Our results indicate that the role of the SAM to drive energy deposition decreases as the size of the AuNP increases. It was determined that 5 nm is the optimum size to exploit the benefits of the SAM on the ionization and selectivity of the AuNPs.
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Highly selective mesoporous sorbents for mercury removal from industrial wastewaterGodongwana, Ziboneni Governor January 2011 (has links)
The results of this study show that novel mesoporous carbons were obtained as inverse replica of SBA-15, HMS and MCM-41 silica templates, with a large pore diameter (2-4 nm), a BET surface area of 1867, 874 and 910 m2g â1 respectively for CA_SBA-15_LPG_105, CA_HMS_LPG_80 and CA_MCM- 41_LPG_80 with bimodal pore size distribution (PSD) in the mesopores range. The results obtained show that mesoporous carbon with graphitic structures can be synthesized via the LPG route.
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Volatile metabolites from microorganisms in indoor environments : sampling, analysis and identificationSunesson, Anna-Lena January 1995 (has links)
Microorganisms are able to produce a wide variety of volatile organic compounds. This thesis deals with sampling, analysis and identification of such compounds, produced by microorganisms commonly found in buildings. The volatiles were sampled on adsorbents and analysed by thermal desorption cold trap-injection gas chromatography, with flame ionization and mass-spectrometric detection. The injection was optimized, with respect to the recovery of adsorbed components and the efficiency of the chromatographic separation, using multivariate methods. Eight adsorbents were evaluated with the object of finding the most suitable for sampling microbial volatiles. Among the adsorbents tested, Tenax TA proved to have the best properties for the purpose. Some carbon-containing adsorbents, e.g., Tenax GR and Carbopack B, showed a catalytic effect on thermal decomposition of some compounds, mainly terpene derivatives. Five fungal species, Aspergillus versicolor, Pénicillium commune, Cladosporium cladosporioides, Paecilomyces variotii and Phialophora fastigiata, and anactinomycete, Streptomyces albidoflavus, were cultivated on various artificial media and/or building materials. Cultivation was performed in culture flasks, provided with air inlet and outlet tubes. Humidified air was constantly led through the flasks, and samples were taken by attaching adsorbent tubes to the outlet tubes of the flasks. The cultivation medium proved to be of vital importance for metabolite production, quantitatively as well as qualitatively. For Streptomyces albidoflavus the effect of medium, cultivation temperature, and oxygen and carbon dioxide levels in the supplied air on the production of volatiles, was studied using multivariate techniques. The medium and the temperature exerted the largest influence, but the oxygen and carbon dioxide levels also affected the amounts of some metabolites produced. The produced volatile metabolites were identified by mass spectrometry and reference compounds. Alcohols, ketones, sulphur compounds and terpenes were most frequently found, but hydrocarbons, ethers and esters were also produced by some species. Among the most commonly produced metabolites, which are also suggested as potential indicator substances for excessive growth of microorganisms in buildings, were 3-methyl-1-butanol, 2-methyl-1-butanol, 3-methyl-2-butanone, 3-methyl-2-pentanone, dimethyl disulphide, -methylfuran, 2,5-dimethylfuran and geosmin. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1995, härtill 5 uppsatser.</p> / digitalisering@umu
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Simulation studies of molecular transport across the liquid-gas interfaceSomasundaram, Theepaharan January 2000 (has links)
No description available.
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Synthesis and characterisation of metal (Fe, Ga, Y) doped alumina and gallium oxide nanostructuresZhao, Yanyan January 2008 (has links)
It is well known that nanostructures possess unique electronic, optical, magnetic, ferroelectric and piezoelectric properties that are often superior to traditional bulk materials. In particular, one dimensional (1D) nanostructured inorganic materials including nanofibres, nanotubes and nanobelts have attracted considerable attention due to their distinctive geometries, novel physical and chemical properties, combined effects and their applications to numerous areas. Metal ion doping is a promising technique which can be utilized to control the properties of materials by intentionally introducing impurities or defects into a material.
γ-Alumina (Al2O3), is one of the most important oxides due to its high surface area, mesoporous properties, chemical and thermal properties and its broad applications in adsorbents, composite materials, ceramics, catalysts and catalyst supports. γ-Alumina has been studied intensively over a long period of time. Recently, considerable work has been carried out on the synthesis of 1D γ-alumina nanostructures under various hydrothermal conditions; however, research on the doping of alumina nanostructures has not been forthcoming. Boehmite (γ-AlOOH) is a crucial precursor for the preparation of γ-Alumina and the morphology and size of the resultant alumina can be manipulated by controlling the growth of AlOOH.
Gallium (Ga) is in the same group in the periodic table as aluminum. β-Gallium (III) oxide (β-Ga2O3), a wide band gap semiconductor, has long been known to exhibit conduction, luminescence and catalytic properties. Numerous techniques have been employed on the synthesis of gallium oxide in the early research. However, these techniques are plagued by inevitable problems. It is of great interest to explore the synthesis of gallium oxide via a low temperature hydrothermal route, which is economically efficient and environmentally friendly.
The overall objectives of this study were: 1) the investigation of the effect of dopants on the morphology, size and properties of metal ion doped 1D alumina nanostructures by introducing dopant to the AlOOH structure; 2) the investigation of impacts of hydrothermal conditions and surfactants on the crystal growth of gallium oxide nanostructures. To achieve the above objectives, trivalent metal elements such as iron, gallium and yttrium were employed as dopants in the study of doped alumina nanostructures. In addition, the effect of various parameters that may affect the growth of gallium oxide crystals including temperature, pH, and the experimental procedure as well as different types of surfactants were systematically investigated.
The main contributions of this study are: 1) the systematic and in-depth investigation of the crystal growth and the morphology control of iron, gallium and yttrium doped boehmite (AlOOH) under varying hydrothermal conditions, as a result, a new soft-chemistry synthesis route for the preparation of one dimensional alumina/boehmite nanofibres and nanotubes was invented; 2) systematic investigation of the crystal growth and morphology and size changes of gallium oxide hydroxide (GaOOH) under varying hydrothermal conditions with and without surfactant at low temperature; We invented a green hydrothermal route for the preparation of α-GaOOH or β-GaOOH micro- to nano-scaled particles; invented a simple hydrothermal route for the direct preparation of γ-Ga2O3 from aqueous media at low temperature without any calcination.
The study provided detailed synthesis routes as well as quantitative property data of final products which are necessary for their potential industrial applications in the future. The following are the main areas and findings presented in the study:
• Fe doped boehmite nanostructures
This work was undertaken at 120ºC using PEO surfactant through a hydrothermal synthesis route by adding fresh iron doped aluminium hydrate at regular intervals of 2 days. The effect of dopant iron, iron percentage and experimental procedure on the morphology and size of boehmite were systematically studied. Iron doped boehmite nanofibres were formed in all samples with iron contents no more than 10%. Nanosheets and nanotubes together with an iron rich phase were formed in 20% iron doped boehmite sample. A change in synthesis procedure resulted in the formation of hematite large crystals. The resultant nanomaterials were characterized by a combination of XRD, TEM, EDX, SAED and N2 adsorption analysis.
• Growth of pure boehmite nanofibres/nanotubes
The growth of pure boehmite nanofibres/nanotubes under different hydrothermal conditions at 100ºC with and without PEO surfactant was systematically studied to provide further information for the following studies of the growth of Ga and Y doped boehmite. Results showed that adding fresh aluminium hydrate precipitate in a regular interval resulted in the formation of a mixture of long and short 1D boehmite nanostructures rather than the formation of relatively longer nanofibres/nanotubes. The detailed discussion and mechanism on the growth of boehmite nanostructure were presented. The resultant boehmite samples were also characterized by N2 adsorption to provide further information on the surface properties to support the proposed mechanism.
• Ga doped boehmite nanostructures
Based on this study on the growth of pure boehmite nanofibre/nanotubes, gallium doped boehmite nanotubes were prepared via hydrothermal treatment at 100ºC in the presence of PEO surfactant without adding any fresh aluminium hydrate precipitate during the hydrothermal treatment. The effect of dopant gallium, gallium percentage, temperature and experimental procedure on the morphology and size of boehmite was systematically studied. Various morphologies of boehmite nanostructures were formed with the increase in the doping gallium content and the change in synthesis procedure. The resultant gallium doped boehmite nanostructures were characterized by TEM, XRD, EDX, SAED, N2 adsorption and TGA.
• Y doped boehmite nanostructures
Following the same synthesis route as that for gallium doped boehmite, yttrium doped boehmite nanostructures were prepared at 100ºC in the presence of PEO surfactant. From the study on iron and gallium doped boehmite nanostructures, it was noted both iron and gallium cannot grow with boehmite nanostructure if iron nitrate and gallium nitrate were not mixed with aluminium nitrate before dissolving in water, in particular, gallium and aluminium are 100% miscible. Therefore, it’s not necessary to study the mixing procedure or synthesis route on the formation of yttrium doped boehmite nanostructures in this work. The effect of dopant yttrium, yttrium percentage, temperature and surfactant on the morphology and size of boehmite were systematically studied. Nanofibres were formed in all samples with varying doped Y% treated at 100ºC; large Y(OH)3 crystals were also formed at high doping Y percentage. Treatment at elevated temperatures resulted in remarkable changes in size and morphology for samples with the same doping Y content. The resultant yttrium doped boehmite nanostructures were characterized by TEM, XRD, EDX, SAED, N2 adsorption and TGA.
• The synthesis of Gallium oxide hydroxide and gallium oxide with surfactant
In this study, the growth of gallium oxide hydroxide under various hydrothermal conditions in the presence of different types of surfactants was systematically studied. Nano- to micro-sized gallium oxide hydroxide was prepared. The effect of surfactant and synthesis procedure on the morphology of the resultant gallium oxide hydroxide was studied. β-gallium oxide nanorods were derived from gallium oxide hydroxide by calcination at 900ºC and the initial morphology was retained. γ-gallium oxide nanotubes up to 65 nm in length, with internal and external diameters of around 0.8 and 3.0 nm, were synthesized directly in solution with and without surfactant. The resultant nano- to micro-sized structures were characterized by XRD, TEM, SAED, EDX and N2 adsorption.
• The synthesis of gallium oxide hydroxide without surfactant
The aim of this study is to explore a green synthesis route for the preparation of gallium oxide hydroxide or gallium oxide via hydrothermal treatment at low temperature. Micro to nano sized GaOOH nanorods and particles were prepared under varying hydrothermal conditions without any surfactant. The resultant GaOOH nanomaterials were characterized by XRD, TEM, SAED, EDX, TG and FT-IR. The growth mechanism of GaOOH crystals was proposed.
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Coal seam gas associations in the Huntly, Ohai and Greymouth regions, New ZealandButland, Caroline January 2006 (has links)
Coal seam gas has been recognised as a new, potential energy resource in New Zealand. Exploration and assessment programmes carried out by various companies have evaluated the resource and indicated that this unconventional gas may form a part of New Zealand's future energy supply. This study has delineated some of the controls between coal properties and gas content in coal seams in selected New Zealand locations. Four coal cores, one from Huntly (Eocene), two from Ohai (Cretaceous) and one from Greymouth (Cretaceous), have been sampled and analysed in terms of gas content and coal properties. Methods used include proximate, sulphur and calorifc value analyses; ash constituent determination; rank assessment; macroscopic analysis; mineralogical analysis; maceral analysis; and gas analyses (desorption, adsorption, gas quality and gas isotopes). Coal cores varied in rank from sub-bituminous B-A (Huntly); sub-bituminous C-A (Ohai); and high volatile bituminous A (Greymouth). All locations contained high vitrinite content (~85 %) with overall relatively low mineral matter observed in most samples. Mineral matter consisted of both detrital grains (quartz in matrix material) and infilling pores and fractures (clays in fusinite pores; carbonates in fractures). Average gas contents were 1.6 m3/t in the Huntly core, 4.7 m3/t in the Ohai cores, and 2.35 m3/t in the Greymouth core. The Ohai core contained more gas and was more saturated than the other cores. Carbon isotopes indicated that the Ohai gas composition was more mature, containing heavier 13C isotopes than either the Huntly or Greymouth gas samples. This indicates the gas was derived from a mixed biogenic and thermogenic source. The Huntly and Greymouth gases appear to be derived from a biogenic (by CO2 reduction) source. The ash yield proved to be the dominant control on gas volume in all locations when the ash yield was above 10 %. Below 10 % the amount of gas variation is unrelated to ash yield. Although organic content had some influence on gas volume, associations were basin and /or rank dependant. In the Huntly core total gas content and structured vitrinite increased together. Although this relationship did not appear in the other cores, in the Ohai SC3 core lost gas and fusinite are associated with each other, while desmocollinite (unstructured vitrinite) correlated positively with residual gas in the Greymouth core. Although it is generally accepted that higher rank coals will have higher adsorption capacities, this was not seen in this data set. Although the lowest rank coal (Huntly) contains the lowest adsorption capacity, the highest adsorption capacity was not seen in the highest rank coal (Greymouth), but in the Ohai coal instead. The Ohai core acted like a higher rank coal with respect to the Greymouth coal, in terms of adsorption capacity, isotopic signatures and gas volume. Two hypothesis can be used to explain these results: (1) That a thermogenically derived gas migrated from down-dip of the SC3 and SC1 drill holes and saturated the section. (2) Rank measurements (e.g. proximate analyses) have a fairly wide variance in both the Greymouth and Ohai coal cores, thus it maybe feasible that the Ohai cores may be higher rank coal than the Greymouth coal core. Although the second hypothesis may explain the adsorption capacity, isotopic signatures and the gas volume, when the data is plotted on a Suggate rank curve, the Ohai coal core is clearly lower rank than the Greymouth core. Thus, pending additional data, the first hypothesis is favoured.
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Κυψέλες καυσίμου στερεού οξειδίου : τριοδική λειτουργία, μαθηματική μοντελοποίηση και μελέτη με θερμοπρογραμματιζόμενη εκρόφηση / Solid oxide fuel cells : triode operation, mathematical modeling and temperature programmed desorption studyΠρεσβύτης, Δημήτριος 11 January 2010 (has links)
Στο πρώτο μέρος της παρούσας διατριβής παρουσιάζεται ο σχεδιασμός, η κατασκευή και η λειτουργία μιας τριοδικής SOFC με state-of-the-art υλικά ηλεκτροδίων. Η τριοδική λειτουργία ενίσχυσε την απόδοση της κυψέλης έως και 7.7% κάτω από μη-ευνοϊκές συνθήκες λειτουργίας. Το δεύτερο μέρος αφορά τη μαθηματική μοντελοποίηση των SOFC. H μοντελοποίηση μόνιμης κατάστασης περιγράφει τη λειτουργία των κεραμομεταλλικών ανόδων μέσω ενός παράγοντα αποτελεσματικότητας, η, ο οποίος σχετίζεται με το αδιάστατο ρεύμα, J, και έναν αδιάστατο ρυθμό αντίδρασης, Φ2. Η μοντελοποίηση λαμβάνει υπ’όψη αποκλειστικά την υπερχείλιση ιόντων οξυγόνου από τον ηλεκτρολύτη και αφορά διάφορες γεωμετρίες των καταλυτικών σωματίων. Το μοντέλο επιβεβαιώνεται ικανοποιητικά από πειραματικά αποτελέσματα σε state-of-the-art κυψέλη SOFC. Για τη μοντελοποίηση της απενεργοποίησης των κεραμομεταλλικών ανόδων προτείνεται ότι η αύξηση του μεγέθους των καταλυτικών σωματίων Ni της ανόδου υπακούει σε μία συνάρτηση εκθετικής αύξησης της ακτίνας. Με τη χρήση θεμελιωδών ηλεκτροχημικών εξισώσεων σχετίζεται ο ρυθμός υποβάθμισης με τη μεταβολή του μήκους ορίου τριών φάσεων, που υπολογίζεται από την συνάρτηση εκθετικής αύξησης της ακτίνας, και με δομικές και λειτουργικές παραμέτρους της ανόδου. Το μοντέλο επιβεβαιώνεται από πειραματικά δεδομένα συστοιχιών SOFC. Τέλος, μελετώνται οι ιδιότητες των κεραμομεταλλικών ανόδων με τη μέθοδο της Θερμοπρογραμματιζόμενης εκρόφησης. Με τη μέθοδο της αέριας ρόφησης αναγνωρίστηκαν τρία κύρια είδη κορυφών τα οποία είναι σε συμφωνία με κορυφές που έχουν παρατηρηθεί σε αντίστοιχα συστήματα. Εκτιμήθηκαν οι ενέργειες ενεργοποίησης της εκρόφησης των κορυφών. Με τη μέθοδο της ηλεκτροχημικής ρόφησης επιβεβαιώθηκε η ύπαρξη των κορυφών και παρατηρήθηκε μετατόπιση της κύριας κορυφής σε υψηλότερη θερμοκρασία εκρόφησης υποδηλώνοντας ισχυρότερη σύνδεση με τον καταλύτη, σε συμφωνία με τη βιβλιογραφία. / In the first part of the present dissertation the design, construction and operation of a triode SOFC with state-of-the-art electrode materials is presented. The triode operation led to an increased performance of the fuel cell up to 7.7% under unfavorable operating conditions. The second part of the dissertation regards the mathematical modeling of SOFC cermet anodes. Under steady state conditions the operation of the cermet anode is described via the use of an effectiveness factor, η, that is related to the dimensionless current of the anode, J, and a dimensionless reaction rate, Φ2. The modeling accounts explicitly for the migration of the oxygen spillover species from the electrolyte and examines various geometries of the catalytic particles. The model is in good agreement with experimental data obtained from state-of-the-art SOFC cells. For the anode degradation modeling it is proposed that the radius of the Ni particles of the follows an exponential growth function, to describe the sintering induced particle growth. Using fundamental electrochemical equations the degradation is linked to the three phase boundary length, that can be estimated from the exponentially growing radius, and operational and structural data of the anode. The model is validated using SOFC stack experimental data. The third part involves the study of SOFC cermet anodes with the use of Temperature Programmed Desorption. Using gaseous adsorption we identified three peaks that are in agreement with peaks observed in similar systems. The activation energies of the desorption peaks were calculated. Using electrochemical adsorption we verified the origin of the peaks. The shift of the main peak towards higher desorption temperature implies stronger bonding of the relevant species with the catalyst, in agreement with literature data.
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Analyse quantitative de la concentration d'hydrogène jouant un rôle dans la fragilisation par l'hydrogène des aciers haute résistance.Larochelle, Jean-Simon 07 1900 (has links)
No description available.
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Nanoparticle Mediated Suppression of Protein AggregationDas, Anindita January 2015 (has links) (PDF)
The increasing demands for biopharmaceuticals to treat different diseases have raised concerns about controlling the quality and efficacy of such pharmaceuticals. The design and formulation of a stable protein or peptide based biopharmaceutical runs into the limitation that at high concentrations (> 100 mg/ml) or during long storage process the drug undergoes aggregation. During synthesis, purification, storage or packaging of these drugs different kinds of stresses like chemical, oxidative, thermal, shear, etc. are encountered. These stresses promote the non-native aggregation of protein and peptide based drugs. Injection or administration of such drugs if contaminated with aggregates causes patient discomfort or development of an antibody which can adversely affect patient’s conditions.
This brings out the necessity of finding a way so that such aggregation is avoided. Nanoparticles have been used as vehicles for drug delivery and diagnostic agents in biology for a while. The surface of the nanoparticles is known to adsorb small as well as large molecules with different kinetics and energetics of interaction. I have used nanoparticles to adsorb proteins to protect them against aggregation when they are subjected to denaturing conditions. The effectiveness of the nanoparticles in stopping protein aggregation, recovery of the proteins and reversibility of the adsorption process, the catalytic activity of the proteins before and after adsorption on the surface have all been studied in details. The work described here has been divided in 8 chapters and the contents of each chapter are described below.
In Chapter 1 I have provided a brief introduction to the protein aggregation problem. The motivation and scope of the current work has been presented in this chapter.
Materials and methods have been described in Chapter 2. Synthesis of gold and silica nanoparticles, their characterization and stability under experimental conditions have been illustrated in this chapter. The spectroscopic assays and techniques which I have used to study the effect of gold and silica nanoparticles on protein aggregation have been discussed at lengths in this chapter.
In Chapter 3 I have demonstrated the effect of gold nanoparticles on thermal aggregation of alcohol dehydrogenase (ADH). The size of the nanoparticle was varied in the range of 15-60 nm and the effect was measured by various spectroscopic assays and techniques. I have observed that gold nanoparticles prevent thermal aggregation of ADH and the efficiency is high. Gold nanoparticles in nanomolar or even picomolar concentrations are capable of preventing the aggregation of ADH at micromolar concentrations.
In Chapter 4 the role of gold nanoparticles as suppressor of protein aggregation was extended to another protein, insulin. Chemically induced aggregation of insulin using dithiothreitol (DTT) in the presence of gold nanoparticles was studied in the same manner as was done for ADH. Similar prevention property of gold nanoparticles was established by making the observation independent of the method of denaturation or the type of protein used in the prevention experiments.
In Chapter 5 huge second harmonic light scattering (SHS) signal from pure gold nanoparticles has been used to measure the free energy of interaction of ADH and insulin with nanoparticles in solution, for the first time. The change in the second harmonic scattered signal was monitored which decreased steadily as a function of added protein concentration to the aqueous solution of gold nanoparticles. The fitting of the second harmonic signal decay was done with a modified Langmuir adsorption isotherm to extract the free energy change in the interaction and the number of protein molecules adsorbed on the surface.
In Chapter 6 I have demonstrated a way to recover the adsorbed ADH and insulin from the gold nanoparticle surface and tested the activity of ADH by an assay. The structure of the proteins in the adsorbed state has been probed by CD spectroscopy and described in this chapter. It is found that ADH retains its activity in the adsorbed state. Both the proteins retain the native secondary structures in their adsorbed state. However, the structures change drastically under denaturing conditions.
In Chapter 7 the effect silica nanoparticles which are known to have hydrophilic surface has been examined on the aggregation of ADH and insulin in pretty much the same way as was done with gold nanoparticles. The efficiency of silica nanoparticle was found to be lower compared to gold nanoparticles. In addition, the size dependency of prevention efficiency of silica and gold nanoparticles was found to be completely opposite to each other.
In Chapter 8 I have presented the overall summary and possible future directions of this work
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Novas abordagens para exploração de reações químicas relativamente lentas em sistemas de análises em fluxo. Aplicações a amostras de relevância agronômica e ambiental / Novel approaches for exploiting relatively slow chemical reactions in flow analysis systems. Applications to relevant agronomic and environmental samplesAna Clara Felix Vida 27 November 2015 (has links)
Diferentes estratégias foram projetadas e desenvolvidas para sistemas de análises em fluxo envolvendo reações químicas relativamente lentas. O aprisionamento da zona da amostra na bobina de reação permite melhorias de sensibilidade em métodos espectrofotométricos em fluxo envolvendo reações catalíticas. Uma característica inerente a esta estratégia é que, de acordo com as baixas concentrações do analito de interesse esperadas nas amostras, pode-se explorar tanto a variação do tempo quanto da temperatura de aquecimento para o desenvolvimento reacional. Esta estratégia evita a geração de bolhas de ar quando temperaturas elevadas são empregadas. O aprisionamento da zona da amostra na bobina de reação em sistema de análises por injeção em fluxo foi aplicado à reação de oxidação do reagente Tiron por peróxido de hidrogênio catalisada por Co(II) para determinação espectrofotométrica de cobalto em gramíneas. O sistema apresentou boas figuras de mérito, tais como repetibilidade [d.p.r. = 0,8% para 0,6 ?g L-1 Co(II), (n = 5)], limite de detecção [0,046 ?g L-1 Co(II)], frequência de amostragem (19 h-1) e consumo de reagente (330 ?g de Tiron por determinação). Os dados de recuperação nas amostras de gramíneas digeridas variaram entre 97% e 113%. O aquecimento explorando o aprisionamento da zona da amostra na cubeta de detecção mostrou-se promissor para implementação de reações relativamente lentas sem a geração de bolhas de ar, e não houve liberação de bolhas mesmo sob a temperatura de 95ºC. Esta estratégia foi aplicada à determinação espectrofotométrica de vanádio em águas minerais envolvendo a oxidação de p-anisidina por bromato catalisada por V(V) e ativada por Tiron. Sob temperatura de 95ºC, boas figuras de mérito foram obtidas, tais como limite de detecção (0,1 ?g L-1), repetibilidade [d.p.r. = 2,1 % para 5,0 ?g L-1 (n = 10)], frequência analítica [25 h-1] e consumo de reagente (3,0 mg de p-anisidina por determinação). Adicionalmente, foi desenvolvido um procedimento analítico em fluxo para monitoramento dos resíduos de ametrina e atrazina potencialmente lixiviáveis em solos, envolvendo também um processo relativamente lento. Um sistema de análises por injeção sequencial foi utilizado para as etapas de dessorção dos herbicidas com solução 0,01 mol L-1 CaCl2 e concentração em fase sólida em linha, seguida da eluição dessas espécies para a separação em uma coluna monolítica C18 conectada a um cromatógrafo líquido por meio de uma válvula de seis vias. Os eluatos eram injetados no cromatógrafo por meio de uma alça de amostragem de 300 ?L conectada à válvula. Boas figuras de mérito foram obtidas, tais como fatores de enriquecimento de 10,2 e 18,8 e limites de detecção de 0,016 e 0,015 mg L-1 para ametrina e atrazina, respectivamente, limite de quantificação de 0,05 mg L-1 para ambos os herbicidas e repetibilidade estimada como 6,3% e 5,1% para 0,05 mg L-1 (n = 10) para ametrina e atrazina, respecivamente. Os dados de adição e recuperação dos herbicidas nos extratos de solos em condições de equilíbrio se situaram na faixa de 85 a 99% / Different approaches to analytical flow systems involving relatively slow chemical reactions were developed. Zone trapping inside the reaction coil enables sensitivity improvements in flow-based spectrophotometric procedures relying on catalytic reactions. The reaction time and/or temperature can be increased for the determination of analytes present in the samples at low concentrations. Exploitation of the strategy avoids the liberation of air bubbles in the analytical path when high temperatures are involved. A flow injection system with zone trapping in the main reactor was developed for the spectrophotometric determination of cobalt in grass samples exploiting the oxidation of Tiron by bromate catalised by Co(II). Good figures of merit such as repeatability [r.s.d. = 0.8% for 0.6 ?g L-1 Co(II), (n = 5)], detection limit [0.046 ?g L-1 Co(II)], sampling frequency [19 h-1] and reagent consumption (330 ?g of Tiron for determination) were attained. Recovery data in grass sample digests varied within 97% e 113%. Zone trapping inside the flow-through cuvette for exploiting high temperatures was also promising for relatively slow reactions, as no liberation of air bubbles was noted even for temperatures as high as 95oC. The approach was applied to the spectrophotometric determination of vanadium in mineral water samples relying on the oxidation of p-anisidine by bromate catalised by V(V) at 95ºC. Good analytical figures of merit such as repeatability [r.s.d. = 2.1% for 5.0 µg L-1 V(V), n = 10], detection limit [0.1 µg L-1 V(V), sample frequency (25 h-1) and reagent consumption (3.0 mg of p-anisidine per determination) were attained. Additionally, an analytical procedure to monitor the potentially leachable ametryn and atrazine residues in soil samples was proposed. As leaching is relatively slow, a sequential injection system was used to perform the herbicide extractions with 0.01 mol L-1 CaCl2 and in-line solid phase extraction followed by elution towards a C18 monolithic column connected to a liquid chomatograph. To this end, the outlet of the column was connected to a 300-µL six-port valve. Regarding analytical performance, enrichment factors and detection limits were 10.2 and 18.8 and 0.016 e 0.015 mg L-1 for ametryn and atrazine, respectively, quantification limits were 0.05 mg L-1 for both herbicides and good repeatability (r.s.d. = 6.3 and 5.1 % for 0.05 mg L-1 of ametryn and atrazine, n = 10) were attained. Recovery data in the soil extracts under equilibrium conditions were within 85 and 99%
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