Physico-chimie de la phase aqueuse des nuages prélevée au sommet du puy de Dôme : caractérisation et réactivité photochimique / Physico-chemistry of the cloud aqueous phase sampled at the top of the puy de Dôme : characterisation and photochemical reactivity

Charbouillot, Tiffany

12 December 2011

Le milieu nuageux est un milieu complexe au sein duquel un grand nombre d’espèces chimiques peuvent être transformées. Dans ce cadre, la caractérisation chimique et la réactivité photochimique de la phase aqueuse des nuages ont été étudiées. La caractérisation chimique de la phase aqueuse des nuages a permis de montrer que les masses d’air échantillonnées au sommet du puy de Dôme sont majoritairement sous trois influences distinctes, à savoir océanique, continentale et anthropique. La distribution des paramètres physicochimiques et des composés inorganiques est dépendante du type de masses d’air échantillonnées. De plus, la quantification des acides carboxyliques et des aldéhydes a permis de mettre en avant la complexité de la matière organique avec la présence d’une multitude de composés encore non identifiés. L’étude de la réactivité photochimique de la phase aqueuse des nuages a également été réalisée, montrant que la capacité photooxydante de la phase aqueuse des nuages ainsi que les vitesses de dégradation de différentes espèces chimiques sont plus importantes pour les masses d’air polluées. Pour la première fois, des vitesses de photoproduction des radicaux hydroxyles ont été évaluées dans la phase aqueuse des nuages, montrant que les ions nitrates et le peroxyde d’hydrogène sont des sources photochimiques majeures des radicaux hydroxyles (représentant jusqu’à 80 % de leur photoproduction totale). / Clouds represent complex media where many species can be transformed. In order to characterize the chemical composition of cloud water and to better understand the processes involved in the transformations of these species, the characterization and the photoreactivity of cloud water were studied. The characterization of cloud water showed that air masses sampled at the puy de Dôme station can be subject to different influences (marine, continental and anthropogenic). The distribution of the physicochemical parameters and of inorganic compounds was different for each kind of air masses. Moreover, the quantification of carboxylic acids and aldehydes showed the complexity of the organic matter contained in cloud water, with the presence of many unknown organic compounds. The photoreactivity of cloud water was also studied, showing that the oxidizing capacity of cloud water and the degradation rate of organic compounds were higher in polluted air masses. For the first time, hydroxyl radical formation rates were determined in cloud water sampled at the puy de Dôme station, showing that nitrate ions and hydrogen peroxide are among the main sources of hydroxyl radicals (contributing up to 80 % of their total photoformation).

Phase aqueuse des nuages

Radicaux hydroxyles

Photoréactivité

Modélisation

Polluants organiques

Cloud water

Hydroxyl radical

Photoreactivity

Multiphase model

Organic polluants

Particulate and gas-phase PCBs and OH-PCBs in Chicago air

Awad, Andrew Magdi

01 July 2015

This study extends the work we have previously done by reporting on both gas-phase and particulate phase PCB concentrations in Chicago air as well as giving a first report on airborne OH-PCBs in Chicago. Gas phase PCB concentrations ranged from 43.1 pg/m³ to 2250 pg/m³, with an average concentration of 594 pg/m³ ± 445 pg/m³, and exhibited strong temporal trends. Particulate phase PCBs accounted on average for 4.3% of total PCBs in a sample. OH-PCBs were detected in both the gas and particulate phase and exhibit characteristics of either emission sources or atmospheric reactions depending on the congener.

Aroclors

hydorxlated polychlorinated biphenyls

hydroxyl radical reactions

PCB congener

polychlorinated biphenyls

semivolatile organic compounds

Civil and Environmental Engineering

Délivrance par ultrasons de chimiothérapie encapsulée dans des liposomes sono-sensibles : contrôle et dosage de la cavitation inertielle ultrasonore / Ultrasonic delivery of chemotherapy encapsulated in sono-sensitive liposomes : control and dosage of ultrasonic inertial cavitation

Somaglino, Lucie

07 January 2011

L'application d'ultrasons sur une tumeur, où des liposomes se sont accumulés, permet potentiellement de libérer le médicament mais aussi d'en favoriser l'absorption dans les cellules. La cavitation inertielle ultrasonore est le phénomène pressenti pour la libération sous ultrasons de médicament encapsulé dans de petits liposomes solides. Elle est très dépendante des conditions expérimentales et peut-être intense et imprévisible. L'objectif principal du travail réalisé dans le cadre de cette thèse est de contrôler et quantifier la cavitation inertielle, pour induire le largage de médicaments encapsulés dans des liposomes. Dans cette optique, une dose de cavitation inertielle (DC), basée sur le filtrage du bruit large bande émis lors de ce régime de cavitation, est mise au point in vitro pour suivre le largage de médicament encapsulé. Sous divers régimes d'ultrasons pulsés, la DC a été validée en dosant chimiquement les radicaux hydroxyles générés lors de l'implosion des bulles. Les tests menés sur diverses formulations de liposomes contenant de la doxorubicine (dox) ont montrés une haute corrélation entre le taux de largage de dox et la DC permettant de conclure que la cavitation inertielle est impliquée dans ce largage. Le rôle de la température sur la production de radicaux hydroxyles et la libération de dox a également été exploré. Les expériences réalisées ont permis de sélectionner les formulations les plus sensibles aux ultrasons pour les tester sur des rats implantés avec des tumeurs prostatiques. Après plusieurs expériences in vivo menées avec différents dispositifs ultrasonores et formulations de liposomes, le bénéfice du traitement combiné a pu être démontré. / The sonication of a tumor, where liposomes have been accumulated, allows potentially to release encapsulated drug and to promote its absorption in cells. Ultrasonic inertial cavitation is supposed to be implicated in the release of drug encapsulated in small solid liposomes under ultrasonic exposure. Inertial cavitation is strongly dependent on experimental conditions and can be very intense and unpredictable. The main objective of this thesis was to control and quantify inertial cavitation in order to induce drug release from liposomes. In this purpose, an inertial cavitation dose (CD), based on broadband noise emission associated with inertial cavitation, was defined to monitor in vitro encapsulated drug release. The CD was chemically validated with the dosing of hydroxyl radicals generated by bubbles collapses under various pulsed ultrasound exposures. A high correlation between doxorubicin (dox) release rate from liposomes and CD was de monstrated for all liposomes formulations tested and under different pulsed ultrasound exposures. The role of temperature on hydroxyl radical production and dox release was also investigated. The performed experiments allowed selecting the liposomes formulations that are the most sensible to ultrasound in order to test them on rats implanted with prostatic tumors. After several campaigns of in vivo experiments performed with various ultrasonic setups and liposomes formulations, the benefit of the combined treatment was demonstrated.

Dose de cavitation

Liposome

Cavitation inertielle

Ultrasons pulsés

Sonochimie

Chimiothérapie

Tumeur

Radicaux hydroxyles

Cavitation Dose

Liposome

Inertial cavitation,

Pulsed ultrasound

Chemotherapy

Tumor

Hydroxyl radical

572.86

Molecular Probes for Biologically Important Molecules: A Study of Thiourea, Hydroxyl radical, Peroxynitrite and Hypochlorous acid

Chakraborty, Sourav

14 May 2010

Numerous chemical species are important to the health of biological systems. Some species can be beneficial at low doses and harmful at high doses. Other species are highly reactive and trigger serious cell damage. Improved methods to detect the presence and activity of such species are needed. In this work, several biologically important species were studied using appropriate analytical techniques. Fluoride is an important species in human physiology. It strengthens teeth and gives protection against dental caries. However, elevated concentrations of fluoride in the body can lead to health problems such as dental and skeletal fluorosis. Reported fluoride sensors used fluorescence quenching methods in determining fluoride concentration. Our study explored synthesis and characterization of 1,8-bis(phenylthioureido) naphthalene (compound 1) as a fluoride sensing molecule. Compound 1 showed a remarkable 40 fold enhancement in fluorescence with 5 eq of fluoride addition. Compound 1 also showed possibility of visual colorimetric sensing with fluoride. Free radical mediated oxidations of biomolecules are responsible for different pathological conditions in the human body. Superoxide is generated in cells and tissues during oxidative burst. Moderately reactive superoxide is converted to peroxyl, alkoxyl and hydroxyl radicals by various enzymatic, chemical, and biochemical processes. Hydroxyl radical imparts rapid, non specific oxidative damage to biomolecules such as proteins and lipids. Superoxide also reacts with nitric oxide in cells to yield peroxynitrite, which is highly reactive and damages biomolecules. Both hydroxyl radical and peroxynitrite readily react with amino acids containing aromatic side chains. Low density lipoprotein (LDL) carries cholesterol in the human body. Elevated concentration of LDL is a potential risk factor for atherosclerosis. Previous research drew a strong correlation between oxidized low density lipoprotein (ox-LDL) and plaque formation in the arterial wall. More importantly, oxidative damage causes structural changes to the LDL protein (apo B-100) which might facilitate the uptake of LDL by macrophages. In this study LDL was exposed to various concentrations of hydroxyl radical peroxynitrite and hypochlorite. Thereafter oxidized amino acid residues in apo B-100 were mapped by LC-MS/MS methods. We found widely distributed oxidative modifications in the apo B-100 amino acid sequence.

fluoride

fluorescence enhancement

thiourea

chromogenic sensing

low density lipoproteins (LDL)

Fenton Chemistry

free radicals

hydroxyl radical

peroxynitrite

hypochlorus acid

surface mapping

proteomics

LC-MS/MS

natural variants

Traitement de l’acétaldéhyde par décharges électriques impulsionnelles dans les mélanges de gaz atmosphériques : cinétique et efficacité énergétique / Treatment of acetaldehyde by pulsed electric discharges in mixtures of atmospheric gases : kinetic and energy efficiency

Faider, Wilfrid

14 February 2013

Cette thèse a pour objet l’analyse de la cinétique de la conversion de l’acétaldéhyde, CH₃CHO, à des concentrations initiales inférieures ou égale à 5000 ppm dans un mélange de gaz à base d’azote et contenant jusqu’à 20% d’oxygène, à température ambiante. L’étude a été réalisée en utilisant trois réacteurs mettant en œuvre des décharges de qualités spatiales différentes. Il s’agit d’un réacteur (UV510) à décharge pré-ionisée (photo-déclenchée) par rayonnement UV produisant un plasma homogène, et de deux réacteurs à décharge à barrière diélectrique (DBD), de géométrie plane (plan-plan) et de géométrie cylindrique (tige-tube) alimentés par impulsion HT et produisant des plasmas non homogènes à faible (plan) ou forte (cylindre) filamentation ; un diagnostic d’imagerie rapide (ns) de la DBD de géométrie plane montre que le plasma peut être considéré quasi-homogène. En s’appuyant sur une modélisation 0D auto-cohérente de la décharge photo-déclenchée, l’étude de la cinétique du mélange N₂/CH₃CHO montre l’importance des états métastables de la molécule d’azote, triplet A³Σu⁺, et singlets (groupe a' ¹∑⁻u, a ¹∏g, et w ¹Δu) dans la dissociation de l’acétaldéhyde. Un coefficient minimum de 6.5×10⁻¹¹ cm³.s⁻¹ est estimé pour le quenching des singlets par l’acétaldéhyde. Le coefficient du triplet est estimé entre 4.2×10⁻¹¹ cm³.s⁻¹ et 6.5×10⁻¹¹ cm³.s⁻¹. Cette dissociation produit des radicaux (CH₃, CH₃CO, HCO, H, O) et des molécules (CH₄, CH₂CO, C₂H₄, C₂H₂, H₂, CO). Ainsi les sous-produits majoritaires mesurés à la fin de la post décharge temporelle sont le méthane, le dihydrogène, le monoxyde de carbone et l’éthane. Les minoritaires sont l’acétylène, l’éthène, l’acétone et l’acétonitrile. Dans les mélanges contenant de l’oxygène, l’importance de la dissociation de CH₃CHO par quenching des états métastables de N₂ diminue au profit des processus d’oxydation par le radical hydroxyle, OH, et l’oxygène atomique, O (³P). La mesure résolue en temps du radical OH dans la post-décharge du réacteur UV510 montre une très forte réactivité de ce radical avec les sous-produits de conversion de l’acétaldéhyde. Une densité maximum de OH égale à 3.5×10¹⁴ cm⁻³ a été mesurée pour 10 % d’oxygène et 5000 ppm d’acétaldéhyde. Le schéma cinétique adopté pour ces mélanges donne, par la modélisation auto-cohérente, une valeur de densité plus élevée. Toutefois, la conversion de l’acétaldéhyde dans N₂/O₂/CH₃CHO est bien expliquée par le modèle, de même que les concentrations produites de méthane et d’éthane. Enfin, la comparaison de l’efficacité énergétique des trois réacteurs étudiés montre que l’homogénéité de la décharge favorise, pour des milieux pauvres en oxygène (moins de 2 %), la conversion de l’acétaldéhyde. / The present study deals with the kinetics analysis of acetaldehyde (CH₃CHO) conversion in electrical discharges with different spatial qualities et at room temperature. Acetaldehyde concentrations up to 5000 ppm in nitrogen-based gas mixture containing up to 20% of oxygen have been investigated. Three different plasma reactors were used: an UV510 reactor producing a homogeneous plasma thanks to a pre-ionization by UV radiation (photo-triggered), a plane-to-plane and a rod-tube dielectric barrier discharges (DBDs) reactors, In both DBDs reactors discharges were driven by high voltage pulses allowing the production of weakly inhomogeneous plasma in the plane geometry and highly filamentary discharges in the cylindrical one. A high speed imaging diagnostic (ns range) of the plane-to-plane DBD shows that the plasma can be considered quasi-homogeneous. Based on a self-consistent 0D model, the kinetics study of the N₂/CH₃CHO mixture conversion in the photo-triggered discharge shows the importance of nitrogen molecule metastable states , i.e. the triplet A³Σu⁺ and the singlets group a' ¹∑⁻u, a ¹∏g, et w ¹Δu, in the acetaldehyde dissociation process. A minimum coefficient of 6.5×10⁻¹¹ cm³.s⁻¹ has been estimated for the quenching of N₂ singlets state by acetaldehyde. For the triplet states quenching the coefficient of has been evaluated between 4.2×10⁻¹¹ cm³.s⁻¹ and 6.5×10⁻¹¹ cm³.s⁻¹. This dissociation process produces radicals as CH₃, CH₃CO, HCO, H, O, and molecules like CH₄, CH₂CO, C₂H₄, C₂H₂, H₂, CO. Thus, the major by-products detected at the end of the post-discharge time are methane, hydrogen, carbon monoxide and ethane; smaller amounts of acetylene, ethene, acetone and acetonitrile were also detected. In containing oxygen mixtures, the importance of the CH3CHO dissociation processes due to N₂ metastable states quenching of decreases in favor of oxidation processes promoted by the hydroxyl radical, OH, and atomic oxygen, O (³P). Time-resolved measurements of the OH radical in the photo-triggered post-discharge show a very high reactivity of this radical with the by-products of acetaldehyde conversion. A maximum density of OH radical equal to 3.5×10¹⁴ cm⁻³ was measured for 10% oxygen and 5000 ppm of acetaldehyde. The kinetic scheme adopted in the self-consistent model for the same gas mixture gives a higher density value; by the way the model is in good agreement with the acetaldehyde conversion in N₂/O₂/CH₃CHO mixtures, as well as with the methane and ethane produced concentrations. Finally, the comparison of the three studied reactors energy efficiency shows that, for low oxygen content (less than 2%), the homogeneity of the discharge promotes the acetaldehyde conversion.

COV

Acétaldéhyde

Conversion

DBD

Décharge photo-déclenchée

Cinétique

Quenching

Métastable d’azote

Radical hydroxyle

OH

VOCs

Acetaldehyde

Conversion

DBD

Photo-triggered discharge

Kinetics

Quenching

Metastable nitrogen

Hydroxyl radical

OH

Études des réactions primaires en solutions par la radiolyse pulsée picoseconde / Picosecond Pulse Radiolysis Study of Primary Reactions in Solutions

El Omar, Abdel Karim

04 November 2013

Après la découverte des rayonnements ionisants et leurs effets chimiques, il était important d’étudier et de comprendre les mécanismes de formations des radicaux libres et des produits moléculaires caractérisés par leurs courtes durées de vie. Ceci a encouragé les groupes de recherches à développer leurs outils pour qu’ils puissent réaliser ces études. De nos jours la radiolyse impulsionnelle se manifeste comme un outil fondamental permettant de sonder les effets chimiques ainsi que les mécanismes réactionnels dans le milieu étudié.Le laboratoire de Chimie Physique d’Orsay « LCP » est un laboratoire interdisciplinaire abritant la plateforme « ELYSE » qui est un centre de cinétiques rapides. Grâce au laser femtoseconde et à l’accélérateur d’électrons picoseconde, nous avons eu la possibilité, dans le domaine de la radiolyse, de remonter en temps, en étudiant les effets chimiques dans un milieu réactionnel, jusqu’à ~ 5 ps.Nous nous sommes intéressés par les réactions primaires induites par les rayonnements ionisants en solution et ELYSE représentait l’outil principal pour ces études. Les résultats obtenus concernent :- La détermination directe du rendement radiolytique du radical hydroxyle « HO• » en fonction du temps à l’échelle de la picoseconde ;- Etude de l’effet direct du rayonnement ionisant sur les solutions aqueuses concentrées ainsi que la vérification de la réaction de transfert d’électron ultrarapide entre le soluté et le trou positif « H2O•+ » issu lors de la radiolyse de l’eau ;- Etude à température ambiante de la réaction de transfert d’électron entre un électron solvaté (donneur d’électron) et un soluté organique (accepteur d’électron) en milieu visqueux ;- Etude à température ambiante de la solvatation de l’électron dans l’éthylène glycol et dans le propan-2-ol. / Following the discovery of ionizing radiations and their chemical effects, it was important to study and comprehend the formation mechanisms of short lived free radicals and molecular products. In order to perform such studies, researchers and research groups worked on developing tools allowing both formation and detection of those species at short time scales. Nowadays, pulse radiolysis imposed itself as a fundamental and efficient tool allowing scientists to probe chemical effects as well as reaction mechanisms in studied media.The laboratoire de Chimie Physique d’Orsay “LCP” is an interdisciplinary laboratory hosting the platform of fast kinetics known as “ELYSE”. Due to its femtosecond laser and its picosecond electron accelerator, we have the possibility to study chemical effects of ionizing radiations interaction with media at ultrashort times up to ~5 ps.Knowing that we are interested in primary reactions induced in aqueous media by ionizing radiations, ELYSE represents the essential tool in performing our studies. The obtained results concern:- First direct determination of hydroxyl radical “HO•” radiolytic yield as function of time at picosecond time scale ;- Direct effect of ionizing radiation in highly concentrated aqueous solutions as well as investigation of the ultrafast electron transfer reaction between solute molecules and positive holes “H2O•+” formed upon water radiolysis ;- Study at room temperature of electron transfer reaction between solvated electron (electron donor) and organic solutes (electron acceptors) en viscous medium ;- Study at room temperature of electron’s solvation dynamics in ethylene glycol and 2-propanol.

Radiolyse pulsée picoseconde

Effet direct

Trou positif

Solvatation

Radical hydroxyle

Picosecond pulse radiolysis

Direct effect

Positive hole

Solvation dynamics

Hydroxyl radical

Sistemas oxidativos e biomiméticos aplicados à hidrólise enzimática de materiais lignocelulósicos / Oxidative-biomimetic systems applied to enzymatic hydrolysis of lignocellulosic materials

Noriega, Omar Antonio Uyarte

29 June 2016

Inúmeros trabalhos da literatura científica mostram que a remoção parcial de lignina é útil para facilitar o processo de sacarificação enzimática de materiais lignocelulósicos. No entanto, a maioria dos processos de deslignificação aplica condições severas de reação e apresenta custos elevados de processo. Uma alternativa aos processos mais severos de deslignificação envolve a aplicação de sistemas biomiméticos. Estes sistemas demandam condições amenas de reação, compatíveis com a etapa de hidrólise enzimática, porém geralmente são mais lentos e menos eficientes do que os pré-tratamentos químicos e quimiotermomecânicos convencionais. Ponderando estes fatos, o objetivo desta tese foi estudar a aplicação de sistemas oxidativos e biomiméticos na deslignificação de materiais lignocelulósicos prévios a uma etapa de hidrólise enzimática da fração polissacarídica. A estratégia de trabalho consistiu em pré-tratar bagaço de cana (foram empregados 3 cultivares diferentes de cana no presente estudo) com um processo quimiotermomecânico (CTM) em condições amenas de reação (5,0% de Na2SO3 e 2,5% de NaOH) seguido de um tratamento biomimético oxidativo. Esta abordagem visou gerar um material parcialmente deslignificado que pudesse ter a recalcitrância significativamente diminuída pela aplicação de um processo biomimético. Um segundo pré-tratamento foi aplicado em condições mais severas de reação (10% de Na2SO3 e 5,0% de NaOH) e visou gerar um material de referência, com baixa recalcitrância. Os sistemas biomiméticos empregados tiveram origem nos processos naturais de biodegradação de madeira por fungos de decomposição branca e parda e envolveram a ação de: a) Manganês peroxidase, Lacase, ferro e Oxigênio; b) reação de Fenton mediada por quelantes. Estes sistemas foram suplementados ou não com ácidos graxos insaturados, visando gerar radicais organoperoxila no caso dos sistemas suplementados. As reações de Fenton mediadas por quelantes apresentaram emissão de quimiluminescência, o que permitiu otimizar o sistema reacional com base na máxima quimiluminescência obtida. A remoção de lignina obtida com o pré-tratamento CTM variou de acordo com a carga de sulfito alcalino empregada, sendo que para as severidades baixa e alta, a remoção de lignina atingiu 26% e 54%, respectivamente. Os sistemas biomiméticos aplicados no bagaço de cana, após pré-tratamento com sulfito alcalino na condição branda, produziram graus de deslignificação variáveis, sendo que as principais remoções de lignina foram obtidas com o tratamento de Fenton mediado por quelantes e com Oxigênio, atingindo remoções acumuladas de lignina de 44% e 62%, respectivamente. Em todos os casos avaliados, a remoção adicional de lignina promoveu maiores eficiências de conversão enzimática das frações polissacarídicas residuais. A maior conversão de celulose e hemicelulose (acima de 80%) foi obtida com o tratamento Fenton mediado por quelantes aplicado sobre um cultivar de cana de açúcar que apresentava elevado teor de ácidos hidroxicinâmicos, sugerindo uma ação eficiente destes sistemas para a remoção destes ácidos hidroxicinâmicos. / The current scientific literature shows that lignin removal can facilitates subsequent processes of enzymatic saccharification of lignocellulosic materials. However, most of the delignification processes use severe reaction conditions and present high process costs. One alternative for the severe delignification processes includes the use of biomimetic systems. These systems can be applied under mild reaction conditions, which are compatible with the enzymatic hydrolysis step. Nevertheless, biomimetic systems usually present low reaction rates and are less efficient than the more severe chemical and chemithermomechancial processes. Weighing these facts, the main subject of the current PhD thesis was to study oxidative-biomimetic systems suitable for delignification of lignocellulosic materials as a previous step to the enzymatic hydrolysis of the polysaccharide fraction. The experimental approach involved the pretreatment of sugar cane bagasse (three different sugar cane cultivars were evaluated) by a chemithermomechanical (CTM) process under mild reaction conditions (5% of Na2SO3 and 2.5% NaOH), followed by an oxidative-biomimetic system. This approach aimed to prepare a partially delignified material suitable to be treated by the subsequent biomimetic systems, providing significant changes in the material recalcitrance. A second pretreatment under more severe reaction conditions (10% Na2SO3 and 5% NaOH) was performed to prepare a reference material with low recalcitrance. The biomimetic systems used in the current work were based on natural wood decay processes involving white- and brown-rot fungi, and include the actions of: a) Manganese peroxidase, Laccase, Iron íons and Oxygen; b) Chelator Mediated Fenton reactions (CMF). This reaction systems used (or not) the presence of unsaturated fatty acids to induce formation of organoperoxyl radicals. The CMF reactions presented chemiluminescence, which enabled the reaction optimization with basis on maximal chemiluminescence. The lignin removal during the CTM pretreatment varied according to the alkaline-sulfite load used in the reaction. The delignification increased with increased alkaline-sulfite loads reaching 26% and 54% for the less severe and more severe reaction conditions, respectively. Biomimetic systems applied over the mild-pretreated sugar cane bagasse produced varied delignification levels, reaching maximal values for cumulative lignin removal of 44% and 62% for the CMF and Oxigen, respectively. In all cases, the supplementary removal of lignin resulted in more efficient enzymatic hydrolysis of the polysaccharide fraction. The highest cellulose and hemicellulose conversions (over 80%) was obtained with the CMF system applied on a sugar cane cultivar that contained high hydroxycinnamic acids contents, suggesting an efficient action of CMF systems for hydroxycinnamic acids removal.

Estudos cinéticos da catálise da reação de fenton por 3,5-di-terc-butil-catecol / Kinetic studies of the catalysis of the fenton reaction by 3,5-di-tert- butyl-catechol

Silva, Volnir de Oliveira

14 May 2010

A reação de Fenton é o nome dado à oxidação de ferro(II) a ferro(III) pela água oxigenada, uma reação que produz espécies com alto poder oxidante como o radical hidroxila. Neste trabalho, foi desenvolvida uma metodologia espectrofotométrica para o acompanhamento da formação de ferro(III) nos momentos iniciais da reação de Fenton. Esta metodologia foi aplicada a quatro conjuntos de reações: (A) o sistema Fenton simples, contendo apenas ferro(II) e H2O2; (B) o sistema A contendo isopropanol, um substrato orgânico simples que sofre principalmente oxidação a acetona; (C) o sistema A contendo o catalisador 3,5-di-terc-butil-catecol (H2DTBCat); (D) o sistema C mais isopropanol, que corresponde ao sistema catalítico completo. Em cada conjunto, variou-se as concentrações de ferro(II) e H2O2. Um modelo cinético, baseado num conjunto de reações explícitas e as respectivas constantes de velocidade, foi desenvolvido para simular a velocidade de formação de ferro(III) para estes quatro conjuntos de reações. Utilizando reações relatadas na literatura, o modelo forneceu simulações que reproduziram satisfatoriamente os dados experimentais dos conjuntos A e B. No caso dos conjuntos C e D, porém, foi necessário propor uma etapa envolvendo a formação de ferro(IV) ou ferril, estabilizado por complexação com o H2DTBCat. Entretanto, mesmo com a inclusão desta espécie, o modelo não captou a complexidade do sistema em altas concentrações de peróxido e ferro. Esta falha foi atribuída à rápida degradação competitiva do H2DTBCat nestas condições, com a subseqüente participação destes produtos de degradação na reação ou como co-catalisadores ou como inibidores. / The Fenton reaction is the name given to the oxidation of iron(II) to iron(III) by hydrogen peroxide, a reaction that produces highly oxidizing species like the hydroxyl radical. In this work, a spectrophotometric methodology is developed to accompany the formation of iron(III) during the initial moments of the Fenton reaction. This methodology was applied to four sets of reactions: (A) the simple Fenton system, containing only iron(II) and H2O2; (B) system A containing isopropanol, a simple substrate that undergoes principally oxidation to acetone; (C) system A containing the catalyst 3,5-di-tert-butyl-catechol (H2DTBCat); (D) system C plus isopropanol, corresponding to the complete catalytic system. For each set of reactions, the concentrations of iron(II) and H2O2 were varied. A kinetic model, based on explicit chemical reactions and their respective rate constants, was developed to simulate the the rate of formation of iron(III) for these four sets of reactions above. Using reactions described in the literature, the model produced simulations that satisfactorily reproduced the experimental data of sets A and B. In the case of sets C and D, however, it was necessary to propose an additional step involving the formation of iron(IV) or ferril, stabilized by complexation with H2DTBCat. Nonetheless, even with the inclusion of this species, the model failed to capture the complexity of the system at high concentrations of peroxide and iron. This failure was attributed to the rapid competitive degradation of H2DTBCat under these conditions, with the subsequent participation of the degradation products in the reaction as either co-catalysts or inhibitors.

Catálise

Catalysis

Chemical kinetics

Ciclo de Hamilton

Cinética química

Fenton reaction

Ferryl

Hamilton cycle

Hydroxyl radical

Íon ferril

Radical hidroxila

Reação de Fenton

Sistemas oxidativos e biomiméticos aplicados à hidrólise enzimática de materiais lignocelulósicos / Oxidative-biomimetic systems applied to enzymatic hydrolysis of lignocellulosic materials

Omar Antonio Uyarte Noriega

29 June 2016

Inúmeros trabalhos da literatura científica mostram que a remoção parcial de lignina é útil para facilitar o processo de sacarificação enzimática de materiais lignocelulósicos. No entanto, a maioria dos processos de deslignificação aplica condições severas de reação e apresenta custos elevados de processo. Uma alternativa aos processos mais severos de deslignificação envolve a aplicação de sistemas biomiméticos. Estes sistemas demandam condições amenas de reação, compatíveis com a etapa de hidrólise enzimática, porém geralmente são mais lentos e menos eficientes do que os pré-tratamentos químicos e quimiotermomecânicos convencionais. Ponderando estes fatos, o objetivo desta tese foi estudar a aplicação de sistemas oxidativos e biomiméticos na deslignificação de materiais lignocelulósicos prévios a uma etapa de hidrólise enzimática da fração polissacarídica. A estratégia de trabalho consistiu em pré-tratar bagaço de cana (foram empregados 3 cultivares diferentes de cana no presente estudo) com um processo quimiotermomecânico (CTM) em condições amenas de reação (5,0% de Na2SO3 e 2,5% de NaOH) seguido de um tratamento biomimético oxidativo. Esta abordagem visou gerar um material parcialmente deslignificado que pudesse ter a recalcitrância significativamente diminuída pela aplicação de um processo biomimético. Um segundo pré-tratamento foi aplicado em condições mais severas de reação (10% de Na2SO3 e 5,0% de NaOH) e visou gerar um material de referência, com baixa recalcitrância. Os sistemas biomiméticos empregados tiveram origem nos processos naturais de biodegradação de madeira por fungos de decomposição branca e parda e envolveram a ação de: a) Manganês peroxidase, Lacase, ferro e Oxigênio; b) reação de Fenton mediada por quelantes. Estes sistemas foram suplementados ou não com ácidos graxos insaturados, visando gerar radicais organoperoxila no caso dos sistemas suplementados. As reações de Fenton mediadas por quelantes apresentaram emissão de quimiluminescência, o que permitiu otimizar o sistema reacional com base na máxima quimiluminescência obtida. A remoção de lignina obtida com o pré-tratamento CTM variou de acordo com a carga de sulfito alcalino empregada, sendo que para as severidades baixa e alta, a remoção de lignina atingiu 26% e 54%, respectivamente. Os sistemas biomiméticos aplicados no bagaço de cana, após pré-tratamento com sulfito alcalino na condição branda, produziram graus de deslignificação variáveis, sendo que as principais remoções de lignina foram obtidas com o tratamento de Fenton mediado por quelantes e com Oxigênio, atingindo remoções acumuladas de lignina de 44% e 62%, respectivamente. Em todos os casos avaliados, a remoção adicional de lignina promoveu maiores eficiências de conversão enzimática das frações polissacarídicas residuais. A maior conversão de celulose e hemicelulose (acima de 80%) foi obtida com o tratamento Fenton mediado por quelantes aplicado sobre um cultivar de cana de açúcar que apresentava elevado teor de ácidos hidroxicinâmicos, sugerindo uma ação eficiente destes sistemas para a remoção destes ácidos hidroxicinâmicos. / The current scientific literature shows that lignin removal can facilitates subsequent processes of enzymatic saccharification of lignocellulosic materials. However, most of the delignification processes use severe reaction conditions and present high process costs. One alternative for the severe delignification processes includes the use of biomimetic systems. These systems can be applied under mild reaction conditions, which are compatible with the enzymatic hydrolysis step. Nevertheless, biomimetic systems usually present low reaction rates and are less efficient than the more severe chemical and chemithermomechancial processes. Weighing these facts, the main subject of the current PhD thesis was to study oxidative-biomimetic systems suitable for delignification of lignocellulosic materials as a previous step to the enzymatic hydrolysis of the polysaccharide fraction. The experimental approach involved the pretreatment of sugar cane bagasse (three different sugar cane cultivars were evaluated) by a chemithermomechanical (CTM) process under mild reaction conditions (5% of Na2SO3 and 2.5% NaOH), followed by an oxidative-biomimetic system. This approach aimed to prepare a partially delignified material suitable to be treated by the subsequent biomimetic systems, providing significant changes in the material recalcitrance. A second pretreatment under more severe reaction conditions (10% Na2SO3 and 5% NaOH) was performed to prepare a reference material with low recalcitrance. The biomimetic systems used in the current work were based on natural wood decay processes involving white- and brown-rot fungi, and include the actions of: a) Manganese peroxidase, Laccase, Iron íons and Oxygen; b) Chelator Mediated Fenton reactions (CMF). This reaction systems used (or not) the presence of unsaturated fatty acids to induce formation of organoperoxyl radicals. The CMF reactions presented chemiluminescence, which enabled the reaction optimization with basis on maximal chemiluminescence. The lignin removal during the CTM pretreatment varied according to the alkaline-sulfite load used in the reaction. The delignification increased with increased alkaline-sulfite loads reaching 26% and 54% for the less severe and more severe reaction conditions, respectively. Biomimetic systems applied over the mild-pretreated sugar cane bagasse produced varied delignification levels, reaching maximal values for cumulative lignin removal of 44% and 62% for the CMF and Oxigen, respectively. In all cases, the supplementary removal of lignin resulted in more efficient enzymatic hydrolysis of the polysaccharide fraction. The highest cellulose and hemicellulose conversions (over 80%) was obtained with the CMF system applied on a sugar cane cultivar that contained high hydroxycinnamic acids contents, suggesting an efficient action of CMF systems for hydroxycinnamic acids removal.

Development of aqueous phase hydroxyl radical reaction rate constants predictors for advanced oxidation processes

Minakata, Daisuke

22 November 2010

Emerging contaminants are defined as synthetic or naturally occurring chemicals or microorganisms that are not currently regulated but have the potential to enter the environment and cause adverse ecological and/or human health effects. With recent development in analytical techniques, emerging contaminants have been detected in wastewater, source water, and finished drinking water. These environmental occurrence data have raised public concern about the fate and ecological impacts of such compounds. Concerns regarding emerging contaminants and the many chemicals that are in use or production necessitate a task to assess their potential health effects and removal efficiency during water treatment. Advanced oxidation processes (AOPs) are attractive and promising technologies for emerging contaminant control due to its capability of mineralizing organic compound via reactions with highly active hydroxyl radicals. However, the nonselective reactivity of hydroxyl radicals and the radical chain reactions make AOPs mechanistically complex processes. In addition, the diversity and complexity of the structure of a large number of emerging contaminants make it difficult and expensive to study the degradation pathways of each contaminant and the fate of the intermediates and byproducts. The intermediates and byproducts that are produced may pose potential effects to human and aquatic ecosystems. Consequently, there is a need to develop first-principle based mechanistic models that can enumerate reaction pathway, calculate concentrations of the byproducts, and estimate their human effects for both water treatment and reuse practices. This dissertation develops methods to predict reaction rate constants for elementary reactions that are identified by a previously developed computer-based reaction pathway generator. Many intermediates and byproducts that are experimentally identified for HO* induced reactions with emerging contaminants include common lower molecular weight organic compounds on the basis of several carbons. These lower carbon intermediates and byproducts also react with HO* at relatively smaller reaction rate constants (i.e., k < 109 M-1s-1) and may significantly affect overall performance of AOPs. In addition, the structures of emerging contaminants with various functional groups are too complicated to model. As a consequence, the rate constant predictors are established based on the conventional organic compounds as an initial approch. A group contribution method (GCM) predicts the aqueous phase hydroxyl radical reaction rate constants for compounds with a wide range of functional groups. The GCM is a first comprehensive tool to predict aqueous phase hydroxyl radical reaction rate constants for reactions that include hydrogen-atom abstraction from a C-H bond and/or a O-H bond by hydroxyl radical, hydroxyl radical addition to a C=C unsaturated bond in alkenes and aromatic compounds, and hydroxyl radical interaction with sulfur-, nitrogen-, or phosphorus-atom-containing compounds. The GCM shows predictability; factor of difference of 2 from literature-reported experimental values. The GCM successfully predicts the hydroxyl radical reaction rate constants for a limited number of emerging contaminants. Linear free energy relationships (LFERs) bridge a kinetic property with a thermochemical property. The LFERs is a new proof-of-concept approach for Ab initio reaction rate constants predictors. The kinetic property represents literature-reported and our experimentally obtained hydroxyl radical reaction rate constants for neutral and ionized compounds. The thermochemical property represents quantum mechanically calculated aqueous phase free energy of activation. Various Ab initio quantum mechanical methods and solvation models are explored to calculate the aqueous phase free energy of activation of reactantas and transition states. The quantum mechanically calculcated aqueous phase free energies of activation are within the acceptable range when compared to those that are obtained from the experiments. These approaches may be applied to other reaction mechanisms to establish a library of rate constant predictions for the mechanistic modeling of AOPs. The predicted kinetic information enables one to identify important pathways of AOP mechanisms that are initiated by hydroxyl radical, and can be used to calculate concentration profiles of parent compounds, intermediates and byproducts. The mechanistic model guides the design of experiments that are used to examine the reaction mechanisms of important intermediates and byproducts and the application of AOPs to real fields.

Aqueous phase free energy of activation

Linear free energy relationships

Group contribution method

Ab initio quantum mechanical calculation

Advanced oxidation processes

Hydroxyl radical

Chemical reactions

Pollutants

Emerging contaminants in water