Global ETD Search

31	Kinetic and Mechanistic Studies on the Removal of Cyanotoxins and Antibiotics with Hydroxyl and Sulfate Radical Based Advanced Oxidation Processes He, Xuexiang 12 September 2014 (has links) No description available. Environmental Engineering advanced oxidation processes microcystin-LR cylindrospermopsin hydrogen peroxide persulfate peroxymonosulfate
32	Formation of mixed Fe"-Fe"' oxides and their reactivity to catalyze chemical oxidation : remediation of hydrocarbon contaminated soils / Formation des composés mixtes Fe"-Fe"' et réactivité catalytique pour l'oxydation chimique : remédiation des sols contaminés par les hydrocarbures Usman, Muhammad 17 November 2011 (has links) Le thème principal de cette recherche est la remédiation des sols contaminés par des hydrocarbures en utilisant des traitements d'oxydation chimique à pH neutre. Les minéraux à base de fer sont susceptibles de catalyser cette réaction d'oxydation. L'étude concerne donc dans un premier temps la synthèse des minéraux réactifs contenant des espèces FeII et FeIII (la magnétite et la rouille verte) et, dans un second temps, leur utilisation pour catalyser l'oxydation chimique. Les procédés d'oxydation testés incluent l'oxydation de type « Fenton-like (FL) » et de type persulfate activé (AP). La formation de la magnétite et de la rouille verte a été étudiée par des transformations abiotiques de différents oxydes ferriques (ferrihydrite, goethite, hématite et lépidocrocite) mis en présence de cations FeII. La magnétite a été utilisée pour catalyser les oxydations (FL et AP) dans la dégradation des hydrocarbures aliphatiques et aromatiques polycycliques (HAP) à pH neutre. Une dégradation importante des hydrocarbures aliphatiques a été obtenue par ces deux oxydants, aussi bien pour des pétroles dégradés naturellement que pour un pétrole brut. L'oxydation catalysée par la magnétite a également été efficace pour la remédiation de deux sols contaminés par HAP provenant d'anciens sites de cokerie. Aucun sous-produit n'a été observé dans nos expériences d'oxydation. En revanche, une très faible dégradation des hydrocarbures a été observée lorsque les espèces FeII solubles ont été utilisées comme catalyseur. Des expériences d'oxydation ont également été réalisées en colonne. Ces études d'oxydation ont révélé l'importance du type de catalyseur utilisé pour l'oxydation, la disponibilité des HAP dans les sols et l'effet de la matrice du sol. Les résultats suggèrent que la magnétite peut être utilisée comme source de fer pour activer les deux oxydations par Fenton-like et persulfate à pH neutre. Ce travail a de fortes implications sur la remédiation par oxydation chimique in situ des sols pollués par des hydrocarbures / The main theme of this research is the use of reactive iron minerals in the remediation of hydrocarbon contaminated soils via chemical oxidation treatments at circumneutral pH. The contribution of this thesis is two-fold including the abiotic synthesis of mixed FeII-FeIII oxides considered as reactive iron minerals (magnetite and green rust) and their use to catalyze chemical oxidation. Oxidation methods tested in this study include Fenton-like (FL) and activated persulfate oxidation (AP). The formation of magnetite and green rust was studied by abiotic FeII-induced transformations of various ferric oxides like ferrihydrite, goethite, hematite and lepidocrocite. Then, the ability of magnetite was tested to catalyze chemical oxidation (FL and AP) for the degradation of aliphatic and polycyclic aromatic hydrocarbons (PAHs) at circumneutral pH. Significant degradation of oil hydrocarbons occurring in weathered as well as in crude oil was obtained by both oxidants. Magnetite catalyzed oxidation was also effective for remediation of two PAHs contaminated soils from ancient coking plant sites. No by-products were observed in all batch slurry oxidation systems. Very low hydrocarbon degradation was observed when soluble FeII was used as catalyst under the same experimental conditions. Magnetite also exhibited high reactivity to catalyze chemical oxidation in column experiments under flow through conditions. Oxidation studies revealed the importance of catalyst type for oxidation, PAHs availability in soils and the soil matrix effect. Results of this study suggest that magnetite can be used as iron source to activate both Fenton-like and persulfate oxidation at circumneutral pH. This study has important implications in the remediation of hydrocarbon polluted soils through in-situ chemical oxidation Transformation abiotique Rouille verte Magnétite Remédiation de sols Hydrocarbures Oxydation chimique Fenton-like Persulfate PH neutre Abiotic transformation Green rust Magnetite Soil remediation Hydrocarbons Chemical oxidation Fenton-like Persulfate Circumneutral pH 628.55 549.526
33	Application of Fe(III)-EDDS complex in advanced oxidation processes : 4-ter-butylphenol degradation / Utilisation du complexe Fe(III)-EDDS dans des procédés d’oxydation avancée : dégradation du 4-tert-butylphénol Wu, Yanlin 16 May 2014 (has links) Dans cette étude, un nouveau complexe de fer est utilisé dans des processus d’oxydation avancée pour la dégradation de polluants organiques présents dans l’eau. Le fer ferrique (Fe(III)) et l’acide éthylène diamine-N,N’-disuccinique (EDDS) forment un complexe Fe(III)-EDDS dont la structure a été mise en évidence durant ce travail. Les propriétés photochimiques du complexe ont ensuite été évaluées en fonction de différents paramètres physico-chimiques dont le pH qui est apparu comme un paramètre clé pour l’efficacité des processus testés. Ensuite nous avons donc travaillé sur l’utilisation de ce complexe dans les processus de Fenton modifié, photo-Fenton et comme activateur des persulfates (S2O82-). Nos expériences ont été réalisées en présence du 4-tert-butylphénol (4-t-BP) qui est connu pour être un perturbateur endocrinien. Nous avons ensuite mis en évidence les conditions optimales du traitement pour la dégradation du 4-t-BP. Il est apparu que le pH joue un rôle très important et qu’en présence de ce complexe de fer, l’efficacité est plus importante pour des pH neutre ou légèrement basique. L’identification des radicaux oxydants responsables de la dégradation du polluant a également été réalisée. Dans ce cadre nous avons montré que le radical sulfate joue un rôle plus important que le radical hydroxyle lors du processus d’activation des persulfates. / Advanced Oxidation Processes (AOPs) have been proved to be successfully applied in the treatment of sewage. It can decolorize the wastewater, reduce the toxicity of pollutants, convert the pollutants to be a biodegradable by-product and achieve the completed mineralization of the organic pollutants. The Fenton technologies which are performed by iron-activated hydrogen peroxide (H2O2) to produce hydroxyl radical (HO•) has been widely investigated in the past few decades. Recently, Sulfate radical (SO4•-) which was produced by the activation of persulfate (S2O82-) is applied to the degradation of organic pollutants in water and soil. It is a new technology recently developed. It is also believed to be one of the most promising advanced oxidation technologies.In this study, a new iron complex is introduced to the traditional Fenton reaction. The ferric iron (Fe(III)) and Ethylene diamine-N,N′-disuccinic acid (EDDS) formed the complex named Fe(III)-EDDS. It can overcome the main disadvantage of traditional Fenton technology, which is the fact that traditional Fenton technology can only perform high efficiency in acidic condition. Simultaneously, EDDS is biodegradable and it is one of the best environment-friendly complexing agents. On the other hand, the transition metal is able to activate S2O82- to generate SO4•-. Therefore, Fe(III)-EDDS will also be applied to activate S2O82- in the present study. 4-tert-Butylphenol (4-t-BP) has been chosen as a target pollutant in this study. It is widely used as a chemical raw material and is classified as endocrine disrupting chemicals due to the estrogenic effects. The 4-t-BP degradation rate (R4-t-BP) is used to indicate the efficiency of the advanced oxidation processes which are based on Fe(III)-EDDS utilization. The main contents and conclusions of this research are shown as follows:In the first part, the chemical structure and properties of Fe(III)-EDDS and the 4-t-BP degradation efficiency in UV/Fe(III)-EDDS system were studied. The results showed that Fe(III)-EDDS was a stable complex which was formed by the Fe(III) and EDDS with the molar ratio 1:1. From the photoredox process of Fe(III)-EDDS, the formation of hydroxyl radical was confirmed including that HO• is the main species responsible for the degradation of 4-t-BP in aqueous solution. Ferrous ion (Fe(II)) was also formed during the reaction. With the increasing Fe(III)-EDDS concentration, 4-t-BP degradation rate increased but is inhibited when the Fe(III)-EDDS concentration was too high. Indeed, Fe(III)-EDDS is the scavenger of HO•. pH value had a significant effect on the degradation efficiency of 4-t-BP that was enhanced under neutral or alkaline conditions. On the one hand, Fe(III)-EDDS presented in the FeL-, Fe(OH)L2-, Fe(OH)2L3-, Fe(OH)4- four different forms under different pH conditions and they had different sensitivity to the UV light. On the other hand, pH value affected the cycle between Fe(III) and Fe(II ). The formation of hydroperoxy radicals (HO2•) and superoxide radical anions (O2•-) (pka = 4.88) as a function of pH was also one of the reasons. It was observed that O2 was an important parameter affecting the efficiency of this process. This effect of O2 is mainly due to its important role during the oxidation of the first radical formed on the pollutant. (...) Photochimie Complexes de fer Fenton Fe(III)-EDDS Radical hydroxyle Persulfate Radical sulfate Perturbateur endocrinien 4-t-BP Photochemistry Fe(III)-EDDS Fenton-like Hydroxyl radical Persulfate Sulfate radical Endocrine disrupting chemicals 4-t-BP
34	Encapsulation de pigments aluminium par un revêtement polymère pour une application peinture poudre Doreau, Nicolas 10 November 2005 (has links) (PDF) La forte croissance du marché des peintures en poudre nécessite le développement de nouvelles matières de charges compatibles, et notamment de grades de pigments aluminium spécifiques pour obtenir des effets métallisés intéressants. Pour ce faire, l'enrobage des pigments dans une couche polymère est une stratégie éprouvée. Cette étude a permis de montrer qu'un nouveau type de traitement simple et propre, en milieu aqueux, est possible grâce à l'utilisation d'un réactif qui joue un double rôle : les ions persulfate permettent, en effet, dans un premier temps d'inhiber la corrosion de l'aluminium par passivation, puis d'amorcer la réaction de polymérisation de monomères acryliques. La mise en oeuvre de conditions de réaction spécifiques permet alors de limiter l'agglomération des particules et de former une couche polymère homogène et uniforme garantissant des effets otiques optimaux. En ce qui concerne l'interaction entre persulfate et aluminium, nous avons mis en évidence une réaction d'oxydation par le persulfate. Son effet est croissant avec le rapport massique ions persulfates / aluminium et des conditions optimales ont été déterminées sur le grade de pigments étudié. Enfin un mécanisme a été proposé pour rendre compte des résultats obtenus lors des tests de dégazage (gassing), du suivi du ph et des observations en microscopie électronique à balayage (MEB). Encapsulation Polymérisation en émulsion Aluminium – Particules micrométriques Passivation Persulfate MMA Peinture poudre métallisée
35	Degradação de parabenos empregando biorreator com membranas e processo oxidativo baseado em persulfato. / Degradation of parabens using membrane bioreactor and persulfate-based oxidative processes. Palharim, Priscila Hasse 04 April 2019 (has links) Os produtos de cuidado pessoal (PCP) são substâncias utilizadas para fins de saúde, beleza e higiene, enquadrando-se como contaminantes de caráter emergente. Dentre os PCP estão os parabenos (alquil-p-hidroxibenzoatos), considerados desreguladores endócrinos, encontrados em águas fluviais e efluentes de estações de tratamento em concentrações na faixa de ng L-1 a ?g L-1. A presença destes compostos nessas matrizes reforça a importância de processos alternativos de tratamento de efluentes, como o processo de biorreator com membranas (MBR) e o processo oxidativo avançado (POA) baseado em persulfato (PS) ativado. Aliando um reator biológico e membranas de separação, o MBR destaca-se como alternativa para obtenção de efluentes de boa qualidade, com remoção de contaminantes por sorção, biodegradação e/ou retenção física. Em contrapartida, o POA com persulfato ativado utiliza radicais sulfato como espécie oxidante para degradação de poluentes. Este trabalho objetivou avaliar a remoção de metilparabeno (MeP) e propilparabeno (PrP) pelo processo MBR, bem como estudar a degradação de tais compostos por persulfato ativado com radiação UVA (UVA/PS) ou ferro de valência zero (Fe0/PS). Objetivou-se, outrossim, avaliar a remoção dos parabenos do permeado do MBR por esses POA. Os resultados mostraram que o processo MBR apresentou eficiência média de 95,9% na remoção de MeP e PrP ([parabenos]0 = 0,5 mg L-1) e eficiência média de 85% na remoção de PrP ([PrP]0 = 10 mg L-1). A degradação de MeP e PrP em mistura (50-500 ?g L-1, cada) por UVA/PS exibiu interferência de um parabeno sobre o outro. Assim, optou-se por investigar a degradação apenas de PrP (1 mg L-1) via UVA/PS e Fe0/PS. Para UVA/PS (120 min), quanto maior a irradiância e a concentração inicial de PS, menor o tempo de meia-vida, sendo possível atingir t1/2 mínimo de 37,9 min, com remoção máxima de 77,3%. Para Fe0/PS (15 min), obteve-se um mínimo de t1/2 igual a 0,65 min, para [PS]0 = 5,38 mmol L-1 e [Fe0]0 = 51,6 mg L-1, com porcentagens de degradação superiores a 97% para todos os ensaios realizados. Nesses casos, a identificação de intermediários de degradação do PrP para os processos UVA/PS e Fe0/PS permitiu comprovar a formação de benzoato de propila, benzoato de metila, ácido 4-hidroxibenzoico e MeP. Finalmente, no tratamento do permeado do MBR, obtiveram-se remoções de PrP de 24,5% para UVA/PS (120 min) e de 61,2% para Fe0/PS (90 min), o que se deve ao efeito da matriz complexa. / Personal care products (PCP) are substances used for health, beauty and hygiene purposes, and are classified as emerging contaminants. Parabens (alkyl-p-hydroxybenzoates), included among the PCPs, are considered endocrine disrupters and found in river waters and effluents from wastewater treatment plants, at concentrations ranging from ng L-1 to ?g L-1. The presence of these compounds in environmental matrices reinforces the importance of alternative effluent treatments, such as membrane bioreactors (MBR) and advanced oxidation processes (AOP) based on activated persulfate (PS). The MBR combines a biological reactor and membrane separation membranes, standing out as an alternative to obtain good quality effluents, with contaminants removed by sorption, biodegradation and/or physical retention. In contrast, the AOP based on activated persulfate uses sulfate radicals as oxidizing species for the degradation of pollutants. This work aimed to evaluate the removal of methylparaben (MeP) and propylparaben (PrP) by the MBR process, as well as to investigate the degradation of these compounds by using persulfate activated with UVA radiation (UVA/PS) or zero valence iron (Fe0/PS). The results showed that the MBR process achieved 95.9% MeP and PrP removals ([parabens]0 = 0.5 mg L-1), and 85% PrP removal ([PrP]0 = 10 mg L-1). However, the degradation of MeP and PrP in the mixture (50-500 ?g L-1, each) by the UVA/PS process exhibited the interference of one paraben over the other. It was therefore decided to investigate the degradation of only PrP (1 mg L-1) via UVA/PS and Fe0/PS. For the UVA/PS process (120 min), the higher the irradiance and the initial PS concentration, the shorter the PrP half-life time, with a minimum t1/2 of 37.9 min and maximum removal of 77.3%. For Fe0/PS (15 min), a minimum t1/2 equal to 0.65 min was achieved for [PS]0 = 5.38 mmol L-1 and [Fe0]0 = 51.6 mg L-1, with percent removals higher than 97% for all the experiments performed. In these cases, the identification of PrP degradation intermediates for the UVA/PS and Fe0/PS processes allowed to prove the formation of propyl benzoate, methyl benzoate, 4-hydroxybenzoic acid, and MeP. Finally, regarding the post-treatment of the MBR permeate, lower PrP removals of 24.5% for the UVA/PS process (120 min), and 61.2% for Fe0/PS (90 min) were obtained, which are due to the effect of the complex aqueous matrix. Activated persulfate Biorreator com membranas (MBR) Ferro de valência zero Membrane Bioreactors (MBR) Parabenos Parabens Persulfato ativado Radiação ultravioleta Reatores bioquímicos UVA radiation Zero valence iron
36	SYNTHESIS, CHARACTERIZATION AND APPLICATIONS OF REDUCED GRAPHENE OXIDE AND COMPOSITE MEMBRANES FOR SELECTIVE SEPARATIONS AND REMOVAL OF ORGANIC CONTAMINANTS Aher, Ashish 01 January 2019 (has links) Among the next generation materials being investigated for membrane development, partially reduced Graphene Oxide (rGO) has received increasing attention from the membrane community. rGO-based nanofiltration membranes have shown promising results in applications such as partial desalination, organic contaminant removal, gas-phase separations, and separations from solvent media. rGO offers a unique platform compared to common polymeric membranes since it can be used for separation applications in both aqueous and organic solvent media. An rGO-based platform could also be utilized to synthesize reactive membranes, giving rGO membranes the additional capability of reactively removing organic contaminants. This research focuses on the synthesis of rGO and nanocomposite membranes for applications including the separation of high-value phenolic compounds from a solvent-water mixture, removal of organic contaminants, and treatment of refinery wastewater. First, the behavior of a rGO membrane in water and isopropanol was investigated along with its ability to separate high-value, lignin-derived oligomeric compounds from a solvent-water mixture. This study revealed the formation of stable sorbates of water in the GO channels that resulted in declined membrane permeance and improved size-exclusion cutoff. Through controlled reduction of GO by heat treatment, it was demonstrated that physicochemical properties of the GO membrane could be modulated and separation performance tuned based on the extent of reduction. A varying degree of interlayer spacing was attained between the GO laminates by controlling the O/C ratio of GO. This allowed the rGO membrane to achieve tunable molecular separation of lignin-derived model oligomeric compounds from a solvent-water mixture. Second, the mechanism of ionic transport through the rGO membrane was studied as well as its application in partial desalination and removal of persistent organic contaminants from water. Through comprehensive experimental investigations and mathematical analysis, along with the aid of the extended Nernst Planck equation, the impacts of steric hindrance and charge interactions on the underlying ion transport mechanism were quantified. Charge interactions were observed to be the dominant exclusion mechanism for the rGO membranes. The application of rGO membranes for treatment of high TDS produced water was investigated with the goal of partial hardness and dissolved oil removal. In addition, this study demonstrated the removal of emerging organic contaminants, specifically perfluorooctanoic acid, by rGO membranes and elucidated a charge interaction-dominated exclusion mechanism for this contaminant, as well. Finally, rGO-based and microporous polyvinylidene fluoride (PVDF)-based catalytic membrane platforms were synthesized for removal of organic contaminants via an oxidative pathway. Herein, an advanced oxidation process was integrated with membrane technology by the in-situ synthesis of Fe-based nanoparticles. The unique capability to oxidatively remove contaminants in a continuous mode of operation was explored in addition to the separation performance of the membrane. The rGO-based platform achieved high oxidative removal of trichloroethylene via a sulfate-free, radical-mediated pathway, while simultaneously removing humic acids from water and potentially eliminating undesired side reactions. A PVDF-based microporous catalytic membrane platform was shown to effectively remove organic impurities, such as Naphthenic acids, from high TDS produced water by the same pathway. The enhancement of reaction extent for elevated temperatures and longer residence times was also quantified in this study. These studies benefit the membrane community in the following ways: 1) The work identifies the critical role of the physicochemical properties of GO, such as the O/C ratio and water sorption, for determining the permeability-selectivity of rGO membranes for solvent nanofiltration. 2) Investigations of ion transport through rGO membranes led to an understanding of a charge-dominated separation mechanism for ion retention. The Nernst-Planck equation-based approach employed in this study would enable further assessment and comparison of rGO membranes under a wide set of parameters. 3) Catalytic membrane platforms (rGO and microporous PVDF-based) were synthesized for conducting advanced oxidation reactions in the porous membrane domain, demonstrating potential applications in environmental remediation of organic contaminants. Graphene Oxide Nanofiltration Organic Solvent Nanofiltration Lignin-derived Oligomers separation persulfate mediated oxidation Nanocomposite membranes Environmental Engineering Membrane Science Polymer Science Transport Phenomena
37	COBALT/PEROXYMONOSULFATE AND RELATED OXIDIZING REAGENTS FOR WATER TREATMENT ANIPSITAKIS, GEORGIOS P. January 2005 (has links) No description available. Advanced Oxidation Technologies peroxymonosulfate hydrogen peroxide persulfate cobalt iron silver transition metals hydroxyl radicals sulfate radicals phenol 2 4-dichlorophenol catalysis ultraviolet UV AOTs

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