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Author: Bo Liu Publisher: ISBN: Category : Languages : en Pages :
Book Description
The growing amount and environmental impact of offshore oily wastewater especially offshore produced water (OPW) have drawn significant attention in recent years. The petroleum hydrocarbons in wastewater can have severe negative effects in a long term on coastal and marine ecosystems if without sufficient treatment before discharge. Polycyclic aromatic hydrocarbons (PAHs) as a representative of dissolved chemical compounds or environmental pollutants in oily wastewater have been a major issue of marine environments due to their carcinogenic or mutagenic, toxic, persistent and bio-accumulative properties. To reduce the negative impact of produced water to the marine ecosystem, it is required to remove all toxicants especially PAHs before discharge. Various challenges have been identified in implementing conventional technologies (e.g., physical separation, chemical oxidation and biological remediation) for treating the dissolved organic pollutants (e.g., PAHs). Therefore, the research and development of more effective technologies to address these concerns are much desired. Photocatalysis generates powerful oxidative radicals which can rapidly mineralize organics especially aromatic compounds, offering a great potential use in removing PAHs from oily wastewater. However, the photocatalytic degradation of organics can be dramatically inhibited by the complex matrix of OPW. Limited in-depth studies were reported on the behaviors and interactions of different components in produced water during photocatalysis. The mechanisms of the interferences are of utmost importance to the development of highly efficiency treatment technologies. The generation of intermediates caused by the complex matrix and inhibited treatment process could further lead to the increase in the toxicity of treated effluent to the marine ecosystem, and consequently reduce its potential in natural attenuation. In addressing these challenges and fulfill the knowledge gaps, this research is focused on the evaluation of the key factors and the mechanisms of OPW matrix in photocatalysis, and the development of enhanced photocatalytic oxidation processes to aid the OPW treatment, thus can achieve both high efficiency in removal of PAHs, and low toxicity and high biodegradability of the effluent. The matrix effect was first investigated in a suspensive photocatalytic oxidation system, in which the synthesized TiO2 nanoparticles were used. It is indicated that the degradation of PAHs was inhibited by the impurities in OPW matrix in many ways: the alkaline-earth cations caused the flocculation of the particle; the insoluble particulate matters competed with PAHs in the adsorption on TiO2; the competition and the fouling effect of other dissolved organic matters were deteriorating the process. To enhance the treatment process, immobilized TiO2 was used instead and it was compared with the TiO2 nano-particles. Improvements were found in both naphthalene adsorption and degradation in the immobilized photocatalytic oxidation system, indicating immobilized TiO2 was more efficient and durable than TiO2 nanoparticles in oily wastewater treatment. The competition of hydrocarbons especially phenols played a key role in the degradation of PAHs. The fouling on the catalyst surface was verified by the scaling of alkaline-earth metals and the deposition of organic matters. Further improvement was aimed at developing a novel UV-light-emitted diode (UV-LED)/TiO2 nanotube array (TNA)/ozonation process for treating OPW. The involvement of ozone was to reduce the competition of other organics and enhance the degradation efficiency. The TNA with hollow 1-D tubular nano-structures was applied because of the combined advantage of nano-particle and immobilization, as well as high quantum yield. UV-LED has the advantage of high energy efficiency and long-life time. In the integrated system, the removal of PAHs can be achieved within 30-min treatment with the half-lives reduced to less than 10 mins. Factorial analysis demonstrates that the best dose of TNA is 0.2 g/L. Light intensity affects the generation of iodine radicals, which is a strong scavenger of ozone thus reduces the efficiency of PAHs removal. Ozone dose is a dominated factor that promotes the degradation. Further results indicate that the degradation of phenols and PAHs with higher solubility favors to undergo to ozone-inducted oxidation, while PAHs with lower solubility are more likely oxidized on the catalyst surface. The toxicity and biodegradability of OPW treated by photocatalytic oxidation were investigated during and after the treatment. Studies on the intermediates formed during the photocatalytic ozonation treatment in the presence of halogen ions reveal the mechanism and various reaction pathways of aromatic compounds. Iodization and bromination were the dominant interfering reactions in sequential stages. Two multivariable regression models were developed to quantify the contributions of key toxicants (e.g., total PAHs, total phenols, dibromo-pentane and bromoform) to the acute toxicity of OPW during the treatment processes. It was observed that by removing the total PAHs and total phenols, the acute toxicity was increased from 3% to 57%, and the biodegradability (BOD28/COD ratio) was doubled more than 80% by the integrated UV-LED/TNA/ozonation process. Further, the biodegradation rate of bromoform was much faster than those of phenols, indicating that the proposed technology features high efficiency and has low impact on marine environment. In this research, I have investigated the matrix effect of OPW on photocatalysis and the impacts to the suspended and immobilized TiO2. A novel integrated UV-LED/TNA/ozonation process was developed to treat OPW. The efficiency of the process, the effects of operational parameters, the intermediates and degradation pathways, and their contribution to the acute toxicity and biodegradability of treated effluent were investigated. The scientific contributions of the research are: 1) revealing and summarizing the key mechanisms of OPW matrix and their key effects on photocatalysis, 2) understanding the interactions of OPW composition with catalyst surface, 3) fulfilling the knowledge gaps on the removal of PAHs from OPW by the UV-A (365 nm) photocatalytic ozonation process, including the interactive mechanisms of the adsorption and photocatalytic oxidation, the behaviors of halogenic ions, and the effects of the operational factors, 4) proposing the altered photodegradation pathways of aromatic organic matter in the presence of halogen ions, and 5) proposing toxicity contribution models targeted on the most toxic compounds in OPW with/without photocatalytic ozonation. The findings of this thesis work also help 1) develop a better strategy to countermeasure the difficulties in the application of photocatalytic oxidation for treating OPW, 2) develop an advanced alternative option for the OPW management, and 3) monitor the composition and toxicity changes during the process and hence the production of by-products in the OPW treatment practice.
Author: Bo Liu Publisher: ISBN: Category : Languages : en Pages :
Book Description
The growing amount and environmental impact of offshore oily wastewater especially offshore produced water (OPW) have drawn significant attention in recent years. The petroleum hydrocarbons in wastewater can have severe negative effects in a long term on coastal and marine ecosystems if without sufficient treatment before discharge. Polycyclic aromatic hydrocarbons (PAHs) as a representative of dissolved chemical compounds or environmental pollutants in oily wastewater have been a major issue of marine environments due to their carcinogenic or mutagenic, toxic, persistent and bio-accumulative properties. To reduce the negative impact of produced water to the marine ecosystem, it is required to remove all toxicants especially PAHs before discharge. Various challenges have been identified in implementing conventional technologies (e.g., physical separation, chemical oxidation and biological remediation) for treating the dissolved organic pollutants (e.g., PAHs). Therefore, the research and development of more effective technologies to address these concerns are much desired. Photocatalysis generates powerful oxidative radicals which can rapidly mineralize organics especially aromatic compounds, offering a great potential use in removing PAHs from oily wastewater. However, the photocatalytic degradation of organics can be dramatically inhibited by the complex matrix of OPW. Limited in-depth studies were reported on the behaviors and interactions of different components in produced water during photocatalysis. The mechanisms of the interferences are of utmost importance to the development of highly efficiency treatment technologies. The generation of intermediates caused by the complex matrix and inhibited treatment process could further lead to the increase in the toxicity of treated effluent to the marine ecosystem, and consequently reduce its potential in natural attenuation. In addressing these challenges and fulfill the knowledge gaps, this research is focused on the evaluation of the key factors and the mechanisms of OPW matrix in photocatalysis, and the development of enhanced photocatalytic oxidation processes to aid the OPW treatment, thus can achieve both high efficiency in removal of PAHs, and low toxicity and high biodegradability of the effluent. The matrix effect was first investigated in a suspensive photocatalytic oxidation system, in which the synthesized TiO2 nanoparticles were used. It is indicated that the degradation of PAHs was inhibited by the impurities in OPW matrix in many ways: the alkaline-earth cations caused the flocculation of the particle; the insoluble particulate matters competed with PAHs in the adsorption on TiO2; the competition and the fouling effect of other dissolved organic matters were deteriorating the process. To enhance the treatment process, immobilized TiO2 was used instead and it was compared with the TiO2 nano-particles. Improvements were found in both naphthalene adsorption and degradation in the immobilized photocatalytic oxidation system, indicating immobilized TiO2 was more efficient and durable than TiO2 nanoparticles in oily wastewater treatment. The competition of hydrocarbons especially phenols played a key role in the degradation of PAHs. The fouling on the catalyst surface was verified by the scaling of alkaline-earth metals and the deposition of organic matters. Further improvement was aimed at developing a novel UV-light-emitted diode (UV-LED)/TiO2 nanotube array (TNA)/ozonation process for treating OPW. The involvement of ozone was to reduce the competition of other organics and enhance the degradation efficiency. The TNA with hollow 1-D tubular nano-structures was applied because of the combined advantage of nano-particle and immobilization, as well as high quantum yield. UV-LED has the advantage of high energy efficiency and long-life time. In the integrated system, the removal of PAHs can be achieved within 30-min treatment with the half-lives reduced to less than 10 mins. Factorial analysis demonstrates that the best dose of TNA is 0.2 g/L. Light intensity affects the generation of iodine radicals, which is a strong scavenger of ozone thus reduces the efficiency of PAHs removal. Ozone dose is a dominated factor that promotes the degradation. Further results indicate that the degradation of phenols and PAHs with higher solubility favors to undergo to ozone-inducted oxidation, while PAHs with lower solubility are more likely oxidized on the catalyst surface. The toxicity and biodegradability of OPW treated by photocatalytic oxidation were investigated during and after the treatment. Studies on the intermediates formed during the photocatalytic ozonation treatment in the presence of halogen ions reveal the mechanism and various reaction pathways of aromatic compounds. Iodization and bromination were the dominant interfering reactions in sequential stages. Two multivariable regression models were developed to quantify the contributions of key toxicants (e.g., total PAHs, total phenols, dibromo-pentane and bromoform) to the acute toxicity of OPW during the treatment processes. It was observed that by removing the total PAHs and total phenols, the acute toxicity was increased from 3% to 57%, and the biodegradability (BOD28/COD ratio) was doubled more than 80% by the integrated UV-LED/TNA/ozonation process. Further, the biodegradation rate of bromoform was much faster than those of phenols, indicating that the proposed technology features high efficiency and has low impact on marine environment. In this research, I have investigated the matrix effect of OPW on photocatalysis and the impacts to the suspended and immobilized TiO2. A novel integrated UV-LED/TNA/ozonation process was developed to treat OPW. The efficiency of the process, the effects of operational parameters, the intermediates and degradation pathways, and their contribution to the acute toxicity and biodegradability of treated effluent were investigated. The scientific contributions of the research are: 1) revealing and summarizing the key mechanisms of OPW matrix and their key effects on photocatalysis, 2) understanding the interactions of OPW composition with catalyst surface, 3) fulfilling the knowledge gaps on the removal of PAHs from OPW by the UV-A (365 nm) photocatalytic ozonation process, including the interactive mechanisms of the adsorption and photocatalytic oxidation, the behaviors of halogenic ions, and the effects of the operational factors, 4) proposing the altered photodegradation pathways of aromatic organic matter in the presence of halogen ions, and 5) proposing toxicity contribution models targeted on the most toxic compounds in OPW with/without photocatalytic ozonation. The findings of this thesis work also help 1) develop a better strategy to countermeasure the difficulties in the application of photocatalytic oxidation for treating OPW, 2) develop an advanced alternative option for the OPW management, and 3) monitor the composition and toxicity changes during the process and hence the production of by-products in the OPW treatment practice.
Author: Jing Ping Publisher: ISBN: Category : Languages : en Pages :
Book Description
Offshore Produced Water (OPW) represents the largest volume waste stream from offshore oil and gas (OOG) production activities. It poses major environmental and operational challenges to offshore petroleum industries for requiring more efficient and environmental friendly on-site management. This is true particularly under growing regulatory and economic pressure to reduce the impact of waste discharges. Conventional on-site OPW monitoring and treatment is mainly focused on the oil and grease portion for meeting the regulatory standards, while limited efforts have been given to dissolved compounds especially including Polycyclic Aromatic Hydrocarbons (PAHs). PAHs are proved as one of the most significant contributors to the ecological hazard posed by OPW discharges because of their toxicity, persistency, and potential for bioaccumulation even at a trace level. As a result, effective measurement of PAHs in OPW is imperative, and advanced on-site treatment of the effluent is desired to improve the conventional systems. This dissertation research focused on the development of new analytical testing methods and photolysis and its enhanced oxidation technologies for treating PAHs in OPW. They are composed of the key tasks including: a) refining of solid-phase extraction (SPE) and liquid-phase microextraction (LPME) pretreatment systems to extract PAHs from OPW; b) enhancement of gas chromotography-mass spectrometry (GC-MS) analytical methods for background and residual PAHs analysis; c) design and fabrication of photochemical oxidation reactors for batch- and bench-scale experiments; d) systematic one-factor-at-a-time (OFAT) analysis of key parameters and factors in the course of direct photolysis and photocatalysis; e) investigation of efficacy, parameters/factors interactions, kinetics and mechanisms of the enhanced hybrid oxidation systems by integrating photolysis and ozonation (O3) and/or hydrogen peroxide (H2O2); and f) development of central composite design (CCD) based response surface modeling (RSM) models for process simulation and optimization. The major contribution of this research is the development of compact, efficient, and eco-friendly technologies for on-site OPW testing and treatment. The developed technologies are proved technically sound by lab experiments with high efficiency in detection and removal of PAHs. The research outcomes bring significant environmental, economic and social benefits to industry, government and academia by providing not only effective but also environmentally benign methods for treating OPW generated from OOG production.
Author: Inamuddin Publisher: Springer Nature ISBN: 303054723X Category : Science Languages : en Pages : 443
Book Description
In the context of climate change and fossil fuel pollution, solar energy appears as a cheap and sustainable fuel for many environmental applications, yet the efficiency of techniques has to be improved. This book reviews recent methods and applications of photocatalysis for the treatment of wastewater containing bacteria, heavy metals, organic pollutants, dyes and tannery effluents. Basics of water pollution, polluted river ecosystems and membranes are also detailed.
Author: Martin M. Halmann Publisher: CRC Press ISBN: 9780849324598 Category : Technology & Engineering Languages : en Pages : 322
Book Description
Photodegradation of Water Pollutants, the only complete survey available of current photocatalytic methods for treating water pollutants, covers all aspects of light-stimulated detoxification. Ideal for researchers and students, this new book explains methods for pollution treatment that have proven more effective than conventional biodegradation. Photodegradation of Water Pollutants examines advanced oxidation processes that have been successful in treating the chemical substances produced by industrial effluents and intensive agriculture. These oxidation processes include irradiation with ultraviolet or visible light, the use of homogenous sensitizers, such as dyes, and the use of heterogeneous photocatalysts, such as dispersed semiconductors. In addition, Photodegradation of Water Pollutants addresses the naturally occurring self-cleaning of some pollutants in sunlit surface waters, as well as several alternative non-photochemical approaches to water treatment. Available treatment options are discussed for the main groups of water pollutants, including toxic inorganic ions (cyanides, heavy metals), hydrocarbon derivatives (oil spills, surfactants, pulp and paper wastes), halocarbons, organo-N, organo-P, and organo-S compounds. The text also contains a unique section on the economics of advanced oxidation pollution treatments.
Author: Elvis Fosso-Kankeu Publisher: John Wiley & Sons ISBN: 1119631416 Category : Science Languages : en Pages : 320
Book Description
Photocatalysts in Advanced Oxidation Processes for Wastewater Treatment comprehensively covers a range of topics aiming to promote the implementation of photocatalysis at large scale through provision of facile and green methods for catalysts synthesis and elucidation of pollutants degradation mechanisms. This book is divided into two main parts namely “Synthesis of effective photocatalysts” (Part I) and “Mechanisms of the photocatalytic degradation of various pollutants” (Part II). The first part focuses on the exploration of various strategies to synthesize sustainable and effective photocatalysts. The second part of the book provides an insights into the photocatalytic degradation mechanisms and pathways under ultraviolet and visible light irradiation, as well as the challenges faced by this technology and its future prospects.
Author: Bo Liu
Author: Bo Liu
Author: Jing Ping
Author: Ho-yin Yip
Author: On Ting Woo
Author: Chad Edward Green
Author: Fan Dong
Author: Inamuddin
Author: Opeyemi Oluseyi Afolabi
Author: Martin M. Halmann
Author: Elvis Fosso-Kankeu