Tratamento eletrolítico de lixiviado de aterro sanitário = Electrolytic treatment of landfill leachate / Electrolytic treatment of landfill leachate

Silveira, Jefferson Eduardo, 1986-

19 December 2012

Orientador: Peterson Bueno de Moraes / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Tecnologia / Made available in DSpace on 2018-08-21T23:07:04Z (GMT). No. of bitstreams: 1 Silveira_JeffersonEduardo_M.pdf: 1833335 bytes, checksum: 71226fb620b38ed3dd8fd9ee6cfac08d (MD5) Previous issue date: 2012 / Resumo: A crescente degradação dos corpos d'água é assunto de constante interesse dos pesquisadores, da opinião pública e da mídia, devido à preocupação com a saúde pública, com os meios de produção e no legado às gerações futuras. Embora nos últimos anos as engenharias química, sanitária e ambiental tenham tido um significativo avanço nos métodos para tratamento de resíduos, alguns tipos de efluentes de composição complexa, como o lixiviado de aterro sanitário, não são adequadamente tratados pelos processos convencionais. Neste trabalho, propôs-se o uso da tecnologia eletroquímica, já utilizada na remedição de diversos tipos de resíduos e efluentes, para o desenvolvimento e aperfeiçoamento de um reator eletroquímico, em escala piloto, para tratamento do lixiviado do aterro sanitário do município de Limeira-SP. O lixiviado de aterro sanitário é um líquido escuro, com potencial patogênico, toxicológico e que pode conter compostos orgânicos como fenóis, pesticidas e íons metálicos. Foi utilizado um reator eletroquímico com eletrodos de titânio recobertos com 70%TiO2/30%RuO2 operando em batelada com recirculação, visando à redução da cor, carga orgânica e toxicidade. A partir dos resultados dos parâmetros físico-químico e biológicos, o sistema foi otimizado quanto à vazão, densidade de corrente, concentração de eletrólitos suporte e tempo de tratamento. Após 60 minutos de tratamento em densidade de corrente de 250 mA cm-2, concentração de eletrólito de 0,5 M de NaCl e vazão de 400 L h-1 foi possível remover 80% de DQO, 75% de N-NH3, 65% de COT e 90% de DBO. Levando-se em conta somente a remoção de amônia, a densidade de corrente mínima de 25 mA cm-2 já teve excelente desempenho após 30 minutos de tratamento. O sistema pode ser considerado economicamente viável para tratar este tipo de efluente em comparação aos tratamentos convencionais normalmente utilizados, com a vantagem de ser rápido, ocupar pouco espaço e não gerar lodo / Abstract: The increase in deterioration in the quality of water bodies is a subject of interest for researchers, public and media due to concern about public health. Although chemical engineering and environmental sciences have been experiencing lately significative advance in methods for wastewaters treatment, some types of effluents with complex composition such as landfill leachate are not adequately treated by conventional processes. In this work, we proposed the use of electrochemical technology, already used in the remediation of several types of waste and effluents, for development and improvement of an electrochemical pilot scale flow reactor for the treatment of raw landfill leachate from Limeira city, SP. The landfill leachate is a dark liquid with toxicological and pathogenic potential and may contain organic compounds such as phenols, pesticides and metallic ions. We used an electrochemical reactor with titanium oxide electrodes coated with 70% TiO2/30% RuO2 operating in batch recirculation mode, aiming to reduce color, organic load and toxicity. The electrochemical system was optimized from physicochemical and biological analyses considering the flow rate, current density, supporting electrolyte concentration and treatment time. Tests in 60 minutes at 250 mA cm-2, NaCl 0.5 M and flow rate of 400 L h-1 resulted on 80% COD, 75% NH3 - N, 65% TOC and 90% of BOD removal. Considering solely the removal of ammonia, 25 mA cm-2 was sufficed to reach a good performance in 30 minutes of treatment. The system showed be economically interesting for the treatment of this type of effluent when compared to conventional treatments normally used, because have the following advantages: higher degradation rates, small footprint, zero or low-generation of sludge / Mestrado / Tecnologia e Inovação / Mestre em Tecnologia

Lixiviado

Aterro sanitário

Processos oxidativos avançados

Eletrólise

Superficie de resposta (Estatistica)

Leachate

Sanitary landfill

Advanced oxidation processes

Electrolysis

Response surface (Statistical).

Využití oxidačních procesů (AOP) pro odstraňování mikropolutantů / Use of oxidation processes (AOP) for removal of micropolutants

Stříteský, Luboš

January 2013

This thesis deals with advanced oxidation processes (AOPs) and it’s use for removal of micropollutants from wastewater. The first chapter explains the need AOPs, water quality, pollution and substances that are present in the water. Further, the first chapter outlines approach of the current legislation to micropollutants. The second chapter explains the theory and principle of operation of AOPs. This chapter is divided into two sections. The first section describes AOPs, which were tested at selected WWTP. In the second section, there are described some other AOPs. The third chapter is a literature retrieval of AOPs dealing with the removal of micropollutants. This chapter is focused on the removal of hormones by AOPs using ozone-based AOPs. The fourth chapter describes the actual testing of selected AOPs. The chapter describes selected WWTP, pilot-scale AOP unit and test results. In the last chapter there is designed and described full-scale AOP tertiary unit for removing of micropollutants. The last chapter also contains economic analysis of the proposed tertiary unit.

Chalcogenide semiconductor photocatalysis for the photocatalytic degradation of organic pollutants in water

Sithole, Manishana Precious

01 1900

This research work discusses the removal of organic pollutants specifically diclofenac and acid blue-25 using chalcogenide semiconductors. Semiconductors are materials that absorb light of specific energy and potentially degrade these organic pollutants into smaller compounds that are not toxic such as carbon dioxide and water. / Civil and Chemical Engineering

Photocatalysis

Semiconductor

Advanced oxidation process

Photocatalytic degradation

Pharmaceuticals

Textile dyes

Mineralization

Organic pollutants

Chalcogenide

Ozonation

Membrane

Heterogeneous

Homogenous

Quantitative Microbial Risk Assessment of Water Treatment Process for Reducing Chlorinous Odor / カルキ臭低減型浄水処理プロセスにおける定量的微生物リスク評価

Zhou, Liang

24 November 2015

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19372号 / 工博第4117号 / 新制||工||1635(附属図書館) / 32386 / 新制||工||1635 / 京都大学大学院工学研究科都市環境工学専攻 / (主査)教授 伊藤 禎彦, 教授 田中 宏明, 教授 米田 稔 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

quantitative microbial risk assessment

censored data

removal and inactivation efficacy

O3/UV advanced oxidation process

axial dispersion reactor model

500

Synthesis of Recyclable Magnetic Metal-ferrite Nanoparticles for the Removal of Contaminants of Emerging Concern in Water

Al Anazi, Abdulaziz H.

January 2018

No description available.

Environmental Engineering

magnetic Co-ferrite nanoparticles

magnetic Zn-ferrite nanoparticles

phenylbenzimidazole-5-sulfonic acid

Diclofenac

advanced oxidation process

reaction byproducts

The Effect of Natural Organic Matter on UV/H₂O₂ Treatment and the Effect of UV/H₂O₂ Treatment on Natural Organic Matter

Metz, Deborah H.

January 2012

No description available.

Environmental Science

UV H2O2

contaminant destruction

byproduct formation potential

advanced oxidation

biofilm potential

Solar concentration for the environment industry: photocatalytic materials and application technologies

Fendrich, Murilo Alexandre

14 January 2021

This thesis presents the achievements pursued during the doctoral course. The work was carried out in the context of the project ERiCSol (Energia RInnovabile e Combustili SOLari), as part of the University of Trento strategic plan for the years 2017-2021. The project was conceived to establish an interdepartmental area to promote the challenge of developing scientific research and technological innovation to increase the competitiveness of Trento at national and international level in the areas of energy and environment. Among all the goals of the project, this work dedicates special attention to 1) development of novel materials for solar photocatalytic reactions and 2) use of renewable energy to push forward applications in water remediation. To accomplish these goals, the research brings a full collection of experimental activities regarding the employment of solar concentration for the environment industry and therefore this document is organized in 9 chapters. In chapter 1, it is presented the introduction outlining the overview of the environment industry, the employment of solar light as energy source and the general and specific objectives. Chapter 2 presents a literature review regarding the last 30 years of applications correlating the use of solar light towards wastewater purification. The chapter reviews the engineering features of solar collectors, photocatalyst materials employed and the panorama of the pollutants investigated up to the present date in solar photocatalysis, presenting comparisons between models and real wastewater approaches. Chapter 3 details the experimental techniques and characterizations employed to sustain the investigation proposed in the thesis. The first part of the chapter explains the features of parabolic dish solar concentrator designed and manufactured by the IdEA group at the physics department of the university of Trento. After, it is presented the pulsed laser deposition, a thin films fabrication technique employed to produce the photocatalysts used on water purification experiments. The second part of the chapter presents the description of the characterization techniques used to reveal the fabricated photocatalyst materials properties. Based on the review on the fundamentals of solar photocatalysis and the experimental techniques, chapters 4 and 5 present a discussion in the field of novel photocatalytic materials capable to operate under concentrated sunlight irradiation. Chapter 4 in special presents the investigation regarding the fabrication of tungsten trioxide (WO3) thin film coatings, bringing the novelty of using pulsed laser deposition as the fabrication method and the evaluation of this material in photocatalysis for the degradation of methylene blue dye model pollutant. Chapter 5 instead, presents the development on Zinc Oxide (ZnO) nanoparticles, bringing an innovative point of view on a “green-synthesis” approach and the material immobilization in film for heterogeneous photocatalysis routes. Chapters 6 and 7 discuss solar photocatalysis aiming to shift applications from model pollutants to real wastewater remediation conditions. Important comparisons are performed and discussed regarding the advantages and existing drawbacks. To fulfill this purpose, chapter 6 presents an application case of solar photocatalysis to the degradation of a surfactant-rich industrial wastewater whereas chapter 7 presents the approach focused on the remediation of organic lead contaminants present on a local water well site in the city of Trento. The last experimental approach of concentrated solar light is presented on chapter 8, dedicated to the application of concentrated sunlight towards waste biomass valorization. Conversely to the application on water previously described, this chapter presents the activity on designing, fabricating and coupling a hydrothermal reactor with concentrated sunlight using it as the driving force to promote degradation of grape seeds evolving into hydrochars with possible valorization of the carbonized material. Lastly, chapter 9 presents the conclusions and suggestions, this item expresses the final considerations on the results of the experimental investigations, advantages and limitations observed, and suggests possible actions for future works.

Solar concentration

Wastewater remediation

Photocatalyst material

Water pollutant

Advanced oxidation process.

[en] PRODUCED WATER TREATMENT IN OIL AND GAS EXTRACTION BY ADVANCED OXIDATION / [pt] TRATAMENTO DE ÁGUA PRODUZIDA NA EXTRAÇÃO DE PETRÓLEO E GÁS POR OXIDAÇÃO AVANÇADA

FERNANDA MCCOMB DE OLIVEIRA

02 September 2024

[pt] Água produzida (AP) é uma das fases geradas a partir da separação trifásica obtida após a extração do petróleo e gás e constitui um efluente industrial. O gerenciamento do seu tratamento para descarte face a alta vazão típica e sensibilidade dos ecossistemas marinhos, é um desafio para empresas que lidam com este tipo de fluido, principalmente na extração offshore. Como este efluente tem uma composição química complexa e variável chegando em até 500 mg/L de compostos orgânicos solúveis em água (WSO), os quais não são facilmente removidos pelos tratamentos físico-químicos convencionais como coagulação e floculação, diversas alternativas de tratamento são adotadas a fim de conseguir eliminar ao máximo óleos e micropartículas de sólidos presentes. Para tal, a AP deve ser tratada antes de ser lançada ao mar ou reutilizada no processo. Contudo, nem sempre as etapas do tratamento conseguem funcionar de maneira ótima para atender a qualidade ambiental regulatória, de modo que a busca por novos processos de tratamento segue sendo de interesse geral. Neste trabalho foram testados processos de oxidação catalisada com íons Fe para incrementar a degradação de WSO, usando amostras reais de AP da Bacia de Campos (RJ, Brasil). Os melhores resultados foram obtidos nas seguintes condições de H2O2 em dose de 1x sem necessidade de catalisador (Fe2+). Nessas ocorreu uma redução de 66 por cento dos orgânicos solúveis, suficiente para manter conformidade com as exigências das normas ambientais para descarte de AP no mar. / [en] Produced water (PW) is one of the phases generated from the three-phase separation obtained after the extraction of oil and gas and constitutes an industrial effluent. The management of its treatment for disposal due to the typical high flow and sensitivity of marine ecosystems is a challenge for companies that deal with this type of fluid, especially in offshore extraction. Since this effluent has a complex and variable chemical composition reaching up to 500 mg/L of water-soluble organic compounds (WSO), which are not easily removed by conventional physicochemical treatments such as coagulation and flocculation, several treatment alternatives are adopted in order to eliminate as much as possible oils and microparticles of solids present. To reach this goal, the PW must be treated before being released into the sea or reused in the process. However, the treatment stages are not always able to function optimally to meet the regulatory environmental quality, so the studies for new treatment processes continues to be part of general interest. In this work, Fe ion-catalyzed oxidation processes were tested to increase WSO degradation, using real PW samples from the Campos Basin (RJ, Brazil). The best results were obtained under the following conditions of H2O2 at a dose of 1x without the need for catalyst (Fe2+). In these, there was a 66 percent reduction in soluble organics, sufficient to maintain compliance with the requirements of environmental standards for water discharge.

[pt] PEROXIDO DE HIDROGENIO

[pt] WSO

[pt] AGUA PRODUZIDA

[pt] PROCESSO DE OXIDACAO AVANCADA

[en] HYDROGEN PEROXIDE

[en] WSO

[en] PRODUCED WATER

[en] ADVANCED OXIDATION PROCESS

Application of Advanced Integrated Technologies (Membrane and Photo-Oxidation Processes) for the Removal of CECs contained in Urban Wastewater

Deemter, Roger Dennis

14 March 2024

[ES] El agua se convirtió en uno de los recursos más escasos de la Tierra. Por eso es necesario desarrollar nuevas tecnologías para el tratamiento adecuado de las aguas residuales urbanas (UWW), permitiendo su reutilización. Múltiples tecnologías han demostrado ser efectivas cuando se aplican individualmente, pero a menudo no se aplican ni se integran en el tratamiento convencional de UWW, lo que resulta en la pérdida de posibles efectos sinérgicos. Por estas razones, la investigación sobre la combinación e integración de estas tecnologías es de suma importancia. Cuando se aplican de esta manera, también se conocen como Tecnologías Integradas Avanzadas. Hecho un trabajo de investigación sobre el rendimiento de una planta piloto de nanofiltración (NF) a escala piloto para UWW, seguido de la aplicación de métodos de tratamiento (químico). Los Procesos de Oxidación Avanzada (AOP), como el proceso (solar) foto-Fenton (SPF), aprovechan el ciclo catalítico del hierro (Fe2+ y Fe3+), la luz UV-vis, junto con un agente oxidante, como el peróxido de hidrógeno (H2O2), produciendo radicales hidroxilo altamente reactivos. Este proceso de foto-Fenton (solar) se aplica a un pH 3, para evitar la precipitación del hierro, o a un pH más alto mediante agentes quelantes, como el ácido etilendiamino-N, N'-disuccínico (EDDS). Los microcontaminantes (MC) usados fueron cafeína, imidacloprid, tiacloprid, carbamazepina y diclofenaco. La preconcentración es un paso esencial antes de aplicar AOP como tratamiento terciario de los efluentes de las plantas de tratamiento de aguas residuales urbanas (EDAR), ya que reduce significativamente el volumen a tratar y, por lo tanto, los costos económicos. El tratamiento de la corriente de concentrado de la NF mediante el proceso de SPF demostró ser efectivo para la eliminación de los MC mencionados anteriormente cuando se utilizó H2O2 como agente de oxidación. Por lo tanto, a una mayor degradación de los MC se adhiere una toxicidad directamente proporcionalmente menor. Las investigaciones incluyen la valorización de los efluentes EDAR mediante la recuperación de amonio, con la eliminación combinada de MC mediante NF y diferentes AOPs, con el fin de producir corrientes de permeado para la fertilización e irrigación directa de cultivos, también conocida como 'fertirrigación'. Esto incluye el proceso de SPF, pero también se combina con procesos de electrooxidación (EO). El SPF fue más efectivo al tratar las corrientes de concentrado de NF a pH circunneutro, con una concentración de MC inferior a 1 mg/L. Las corrientes de concentrado de NF altamente salinas son ideales para ser tratadas mediante procesos de EO, por sus alta conductividad, con un consumo eléctrico significativamente menor con la asistencia solar. La eficiencia de retención de MC por NF y la toxicidad después de los tratamientos con AOP también se evaluaron mediante la determinación de la fitotoxicidad del permeado. Los resultados mostraron que los permeados utilizados para los cultivos (Sorghum saccharatum, Sinapis alba, Lepidium sativum) redujeron la germinación de las semillas. Contrariamente, se observó que la irrigación con los permeados producidos generalmente promovió el desarrollo de las raíces, mientras que el desarrollo de los brotes prosperó solo cuando se usaron permeados que tenían factores de concentración inferiores al factor de concentración 2. Los estudios mostraron que los permeados deberían diluirse primero en un mínimo del 50%, para ser adecuados para la irrigación directa. El trabajo también incluyó la evaluación de una membrana de ultrafiltración (UF) cerámica foto catalítica TiO2-ZrO2 previamente desarrollada. La disminución del flujo puede revertirse cuando se irradia la membrana UF cerámica con luz en un simulador solar. La retención microbiológica de la membrana UF fue determinada utilizando una cepa bacteriana Gram negativa, Pseudomonas aeruginosa y fue capaz de retener consistentemente hasta un orden de magnitud de 1 x 104 UFC/ml. / [CA] L'aigua es va convertir en un dels productes bàsics més escassos de la Terra. Per tant, cal desenvolupar noves tecnologies, com el tractament adequat de les aigües residuals urbanes (UWW) per a la seva reutilització. Múltiples tecnologies avançades es demostren efectives quan s'apliquen únicament. Aquestes tecnologies sovint no s'apliquen ni s'integren en el tractament UWW convencional. Com a resultat, es perd possibles efectes sinèrgics. Per aquests motius, la investigació sobre la combinació i integració d'aquestes noves tecnologies és de la màxima importància. Quan s'apliquen així, aquestes tecnologies combinades també es coneixen i s'indiquen com a Tecnologies Integrades Avançades. Es va realitzar un treball de recerca sobre el rendiment d'una planta de nanofiltració (NF) a escala pilot per a la preconcentració d'UWW, seguida de l'aplicació de mètodes de tractament (químics), per tal de tractar els corrents de concentrat i permeat produïts. Els processos d'oxidació avançats (AOP), com el procés foto-Fenton (solar) (SPF), fan servir el cicle catalític del ferro (Fe2+ i Fe3+), la llum UV-vis, juntament amb un agent oxidant, com el peròxid d'hidrogen (H2O2), produint radicals hidroxil altament reactius i no selectius. Aquest procés SPF s'aplica a pH3, per tal d'evitar la precipitació del ferro, o a pH circumneutral aplicant agents quelants com l'àcid etilendiamina-N, N¿-disuccinic (EDDS). La preconcentració és un pas essencial abans d'aplicar els AOP com a tractament terciari d'efluents d'EDAR, ja que redueix significativament el volum a tractar i, per tant, els costos globals. El tractament del corrent de concentrat del NF mitjançant el procés SPF va demostrar ser eficaç per a l'eliminació de diferents microcontaminants (MC) quan s'utilitzava H2O2 com a agent d'oxidació. Per al qual una degradació de MC més alta s'adhereix a una toxicitat menor directament proporcional. Els seleccionats (MC) van ser cafeïna, imidacloprid, tiacloprid, carbamazepina i diclofenac. Els treballs de recerca posteriors van tractar la valorització dels efluents d'EDAR mitjançant la recuperació d'amoni, amb l'eliminació combinada de MC per NF i diferents AOP avançats, per tal de produir corrents permeats per a la fertilització directa dels cultius i el reg, també anomenats "fertirrigació". Inclou SPF, però també combinat amb processos d'electrooxidació (EO). El SPF va ser més eficaç quan es tractaven corrents de concentrat de NF a pH circumneutral, a una concentració de MC inferior a 1 mg/L, per obtenir una degradació ràpida de MC. Els corrents concentrats de concentrat NF altament salins són ideals per ser tractats mitjançant processos EO, alhora que posseeixen una alta conductivitat, i un menor consum elèctric significatiu per assistència solar. També es va avaluar l'eficiència de retenció de MC per NF i la toxicitat després dels tractaments amb AOP determinant la fitotoxicitat del permeat. Els resultats van mostrar que els permeats podrien reduir la germinació de llavors si s'utilitzaven per a cultius (Sorghum saccharatum, Sinapis alba, Lepidium sativum). Al contrari d'això, es va demostrar que el reg amb els permeats produïts afavoria generalment el desenvolupament de les arrels, mentre que el desenvolupament dels brots només va prosperar quan s'utilitzaven permeats que tenien factors de concentració inferiors a 2. Els estudis de toxicitat van mostrar que els corrents de permeat s'havien de diluir primer amb un mínim del 50% aigua dolça. El treball de recerca realitzat també va incloure l'avaluació d'una membrana d'ultrafiltració ceràmica (UF) fotocatalítica TiO2-ZrO2 desenvolupada prèviament. La disminució del flux es pot revertir quan la membrana fotocatalítica UF va ser irradiada per llum en un simulador solar. La retenció microbiològica de la membrana UF es va determinar mitjançant el desplegament d'una soca bacteriana gramnegativa, Pseudomonas aeruginosa, ser capaç de retenir constantment fins a un ordre de magnitud d'1 x 104 CFU/ml. / [EN] Water turned to be one of Earths scarcest commodities. Therefore, novel technologies need to be developed, as appropriate treatment of produced urban wastewaters (UWWs) for its reuse as irrigation waters or aquifer recharge. Multiple advanced technologies are proven effective when applied solely. These technologies are often not applied or integrated into conventional UWW treatment. Resulting in missing out on potential synergetic effects. For these reasons that research into the combining and integration of these novel technologies is of the utmost importance. When thus applied, these combined technologies are also known and indicated as Advanced Integrated Technologies. Research work was conducted on the performance of a pilot scale nanofiltration (NF) plant for UWW pre-concentration, followed by the application of (chemical) treatment methods, in order to treat the produced concentrate and permeate streams. Advanced Oxidation Processes (AOPs), such as the (solar) photo-Fenton process make use of the catalytic cycle of iron (Fe2+ and Fe3+), UV-vis light, along with an oxidizing agent, such as hydrogen peroxide (H2O2), producing highly reactive and non-selective hydroxyl radicals (¿OH). This (solar) photo-Fenton process is applied at acidic pH3, in order to prevent iron precipitation, or at circumneutral pH by applying chelating agents such as Ethylenediamine-N, N¿-disuccinic acid (EDDS). Preconcentration is an essential step before applying AOPs as tertiary treatment of UWWTP effluents, as it significantly lowers the to be treated volume, and therefore the overall costs. Treating the concentrate stream from the NF by the solar photo-Fenton process showed to be effective for the removal of different microcontaminants (MCs) when H2O2 was used as an oxidation agent. Opposite to that, the application of persulfate and its derived radicals showed lower degradation of the selected MC. For which a higher MC degradation is adhered to a directly proportional lower toxicity. Selected (MCs) were caffeine, imidacloprid, thiacloprid, carbamazepine, and diclofenac. Further research work covered UWWTP effluent valorization by the recovery of ammonium, with combined MC elimination by NF and different advanced AOPs, in order to produce permeate streams for direct crop fertilization and irrigation, also called 'fertigation'. Including solar photo-Fenton, but also combined with electrooxidation (EO) processes. Solar photo-Fenton was most effective when treating NF concentrate streams at circumneutral pH, at MC concentration lower than 1 mg/L, to obtain rapid MC degradation. High saline and concentrated NF concentrate streams are ideal to be treated by EO processes, while possessing high conductivity. Obtaining significant lower electric consumption by solar assistance. MC retention efficiency by NF and toxicity after AOP treatments was also assessed by determining the permeate phytotoxicity. Results showed that permeates could lower seed germination if they would be used for crops (Sorghum saccharatum, Sinapis alba and Lepidium sativum). Contrary to that, it was showed that irrigation with the produced permeates generally promoted root development, while shoot development only thrived when using permeates which had concentration factors lower than 2. Toxicity studies showed that permeate streams should first be diluted with a minimum of 50% fresh water, in order to be suitable for direct crop irrigation in agriculture. Conducted research work also included the assessment of a priorly developed (collaboration with an PhD within MSCA AQUAlity) photocatalytic TiO2-ZrO2 ceramic ultrafiltration (UF) membrane. Flux decline can be reversed when the photocatalytic UF membrane was irradiated by light in a solar simulator. Microbiological retention of the UF membrane was determined by deploying a Gram-negative bacterial strain, Pseudomonas aeruginosa (P. Aeruginosa). It was able to consistently retain till an order of magnitude of 1x10^4 CFU/ml. / This PhD Thesis has received funding from the European Union’s Horizon 2020 research and innovation program, the AQUAlity project, under the Marie SkłodowskaCurie grant agreement No 765860. Performing research work at CIEMAT – Plataforma Solar de Almería. / Deemter, RD. (2024). Application of Advanced Integrated Technologies (Membrane and Photo-Oxidation Processes) for the Removal of CECs contained in Urban Wastewater [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/203099

Microcontaminants

Advanced oxidation processes

Membrane separation

Photo-Fenton

Microcontaminantes

Procesos avanzados de oxidación

Separación por membrana

Foto-fenton

QUIMICA FISICA

Integrated processes for removal of persistent organic pollutants : soil washing and electrochemical advanced oxidation processes combined to a possible biological post-treatment

Mousset, Emmanuel, Mousset, Emmanuel

02 December 2013

Soils contaminated by hydrophobic organic pollutants like polycyclic aromatic hydrocarbons (PAHs) are a common concern since they are extremely difficult to remove and their potential toxicological impacts are significant. As an alternative to traditional thermal or physical treatments, soil washing and soil flushing processes appear to be conceivable and efficient approaches, especially for higher level of pollution. However, the treatment of highly loaded soil washing/flushing solutions is another challenge to overcome. In that way, a new integrated approach is suggested: soil washing/flushing processes combined to an electrochemical advanced oxidation process (EAOP) in a combination with a recirculation loop (to save extracting agents) and/or a biological post-treatment step (to minimize energy cost).Extraction efficiency of the extracting agent like hydroxypropyl-beta-cyclodextrin (HPCD) is compared to the traditional non-ionic surfactant Tween 80 in synthetic and real soil washing solutions. A new simple fluorescent sensitive and selective quantification method is developed to monitor Tween 80 oxidation. Two EAOPs were compared: electro-Fenton (EF) and anodic oxidation (AO). Platinum (Pt) (in EF process) and boron doped diamond (BDD) (in both treatment) anodes are the respective electrodes employed to recycle effluents and to consider a biological post-treatment, respectively. Regarding the extracting agent recovery, the biodegradability evolution of effluent and the energy consumption (in kWh (kgTOC)-1) during EAOP, HPCD is more advantageous than Tween 80. However, in terms of extraction efficiency, costs of extracting agents and impact on soil respirometry, Tween 80 is much more efficient. By considering all these advantages and drawbacks, Tween 80 could still appear to be the best option

Soil washing

Polycyclic aromatic hydrocarbons (PAHs)

Cyclodextrins

Surfactants

Biodegradability