Heterogeneous Photocatalytic Treatment of Wastewater from Amine-based Carbon Capture Plants PDF Download
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Author: Kishore Kumar Reddy Bommavaram
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
Amine-based Carbon Capture (ABCC) is the advanced, cost-effective technology used to control climate change by capturing CO! emissions. Although it has been demonstrated commercially, amine degradation poses a significant threat to humans and aquatic life. Amine degradation produces a wide variety of complex products. Some of them are carcinogenic and mutagenic such as nitrosamines and some organic acids that have demonstrated acute toxicity for laboratory animals. In order to mitigate the adverse impact of these compounds on human health and aquatic life, heterogenous photocatalysis, an advanced oxidation process, which can degrade a wide variety of chemical species with the potent reactive hydroxyl radicals, was considered for the degradation of these compounds. The photocatalytic degradation of N-Nitrosodiethylamine (NDEA), acetic acid and formic acid were tested using various metal impregnated TiO2 such as Fe, Co, Ni and Cu. The operational parameters for the photocatalytic degradation process were chosen as solution pH, catalyst dose and metal impregnation percentage (imp %). Various techniques were used for the catalyst characterization such as Thermogravimetric Analysis (TGA), X-Ray Fluorescence Spectrometer (XRF), Brunauer-Emmett-Teller (BET), UV-visible spectrophotometer (UV-Vis), Scanning electron microscope (SEM), and X-ray diffraction (XRD). Designing the experiments, optimization, and impact of the parameters on the photocatalytic degradation of NDEA, acetic acid, and formic acid were analyzed using a Facecentered- central composite design (FC-CCD) in Response Surface Methodology (RSM) by Statease Design expert software. Various regression models were tested using ANOVA to fit between the responses (NDEA, acetic acid, and formic acid) of FC-CCD experimental runs and the independent variables. The quadratic model was analyzed as the best fit for all the responses and the independent variables by eliminating insignificant factors. This model was best demonstrated for all the catalysts such as Fe, Co, Ni, and Cu impregnated TiO2. The interaction between the three variables and the responses were studied and presented in three-dimensional graphical representation. pH was found as an important factor for all three responses. The optimum conditions for the degradation of NDEA, acetic acid and formic acid using Fe-TiO2 catalyst were found as 3.65, 1.5 g/l, and 4.46. Whereas for the Co-TiO2 catalyst the optimum conditions were pH 3.77, catalyst dose of 0.95 g/l, and a metal impregnation percentage of 5. For the Ni-TiO2 the optimum conditions were pH-5.89, dose-0.5 g/l, and imp % of 3.18. A pH of 4.71, dose of 1.5 g/l and imp % of 4.66 were found as optimum conditions for Cu-TiO2. The optimum conditions of the parameters for the photocatalytic degradation of NDEA, acetic acid, and formic acid were determined using RSM and the average degradation efficiency of all the compounds reached 93.1% for Fe-TiO2, 92.08% for Co-TiO2. 89.09% for Ni-TiO2, 88.81% for Cu-TiO2, and 86.3% for TiO2 at the optimum conditions.
Author: Kishore Kumar Reddy Bommavaram
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
Amine-based Carbon Capture (ABCC) is the advanced, cost-effective technology used to control climate change by capturing CO! emissions. Although it has been demonstrated commercially, amine degradation poses a significant threat to humans and aquatic life. Amine degradation produces a wide variety of complex products. Some of them are carcinogenic and mutagenic such as nitrosamines and some organic acids that have demonstrated acute toxicity for laboratory animals. In order to mitigate the adverse impact of these compounds on human health and aquatic life, heterogenous photocatalysis, an advanced oxidation process, which can degrade a wide variety of chemical species with the potent reactive hydroxyl radicals, was considered for the degradation of these compounds. The photocatalytic degradation of N-Nitrosodiethylamine (NDEA), acetic acid and formic acid were tested using various metal impregnated TiO2 such as Fe, Co, Ni and Cu. The operational parameters for the photocatalytic degradation process were chosen as solution pH, catalyst dose and metal impregnation percentage (imp %). Various techniques were used for the catalyst characterization such as Thermogravimetric Analysis (TGA), X-Ray Fluorescence Spectrometer (XRF), Brunauer-Emmett-Teller (BET), UV-visible spectrophotometer (UV-Vis), Scanning electron microscope (SEM), and X-ray diffraction (XRD). Designing the experiments, optimization, and impact of the parameters on the photocatalytic degradation of NDEA, acetic acid, and formic acid were analyzed using a Facecentered- central composite design (FC-CCD) in Response Surface Methodology (RSM) by Statease Design expert software. Various regression models were tested using ANOVA to fit between the responses (NDEA, acetic acid, and formic acid) of FC-CCD experimental runs and the independent variables. The quadratic model was analyzed as the best fit for all the responses and the independent variables by eliminating insignificant factors. This model was best demonstrated for all the catalysts such as Fe, Co, Ni, and Cu impregnated TiO2. The interaction between the three variables and the responses were studied and presented in three-dimensional graphical representation. pH was found as an important factor for all three responses. The optimum conditions for the degradation of NDEA, acetic acid and formic acid using Fe-TiO2 catalyst were found as 3.65, 1.5 g/l, and 4.46. Whereas for the Co-TiO2 catalyst the optimum conditions were pH 3.77, catalyst dose of 0.95 g/l, and a metal impregnation percentage of 5. For the Ni-TiO2 the optimum conditions were pH-5.89, dose-0.5 g/l, and imp % of 3.18. A pH of 4.71, dose of 1.5 g/l and imp % of 4.66 were found as optimum conditions for Cu-TiO2. The optimum conditions of the parameters for the photocatalytic degradation of NDEA, acetic acid, and formic acid were determined using RSM and the average degradation efficiency of all the compounds reached 93.1% for Fe-TiO2, 92.08% for Co-TiO2. 89.09% for Ni-TiO2, 88.81% for Cu-TiO2, and 86.3% for TiO2 at the optimum conditions.
Author: Obed Yeboah Boakye
Publisher:
ISBN:
Category :
Languages : en
Pages : 0
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Book Description
Post combustion carbon capture, a promising technology for capturing the superabundant CO2 produced by various industries has received much research and industrial attention. The use of amines for this capture process comes with its own disadvantage in that it degrades into other products some of which are harmful to the ecosystem upon its release into the environment. Chief of these degradation products are the mutagenic and carcinogenic nitrosamines which have received much research attention in both carbon capture processes and wastewater treatment plant processes. Several treatment methods such as biological methods, activated carbon, UV in conjunction with ozone or reverse osmosis and other catalytic destruction methods have be employed so far in treatment wastewater comprising of nitrosamines. However, in this study, an advanced oxidation process (AOP) named heterogeneous photocatalysis is used as a means of treating N-Nitrosodiethylamine (NDEA) wastewater stream using tungsten trioxide based catalysts. Tungsten trioxide (WO3) is synthesized using Thermal Treatment Method (TTM) and Hard Template Replication Method (HTRM) to help investigate the effect of morphological and structural property changes on the NDEA wastewater degradation process. WO3 was also impregnated with other metals such Lanthanum (La), Iron (Fe), Chromium (Cr) and Silver (Ag) to help improve its light absorption ability for the photocatalytic reaction. These synthesized catalysts were characterized using UV-Vis spectroscopic technique to obtain their light harnessing ability as well as their band gap energies. The surface area and pore structure of the pristine and doped catalysts were also investigated using the Brunauer-Emmett-Teller (BET) and Barrett-Joyner-Halenda (BJH) technique. The crystallinity of the catalysts and their crystallite sizes were determined by employing the X-ray Diffraction (XRD) technique. The surface morphology and catalyst composition were also investigated by employing the use of Scanning Electron Microscopy coupled with Energy Dispersive Spectroscopy (SEM-EDS). Photocatalytic NDEA degradation using the synthesized WO3 based catalysts was investigated as a function of three input factors viz. catalyst loading (0.5-5%), solution pH (5-9) and catalyst concentration (0.5-1 g/L) by using Face-Centred Central Composite Design (FCCCD) adapted from response surface methodology (RSM). Using NDEA degradation efficiency as response, a 17-run experiment matrix was generated by the chosen design to investigate the interaction effects of the three above-mentioned input variables. From the results, a compact quadratic model showing high significance (p 0.05) was developed by means of analysis of variance (ANOVA), It predicted the experimental results with good accuracy as seen from the good coefficients of determination values (R2 0.9). The pH of the solution (5) was found to be the most significant design factor having a positive impact on NDEA degradation as its value decreases. The mean degradation efficiency of NDEA was 86.48% for La/WO3, 84.03% for Cr/WO3, 88.90% for Ag/WO3 and 93.03% for Fe/WO3. Using wastewater effluent volume of 148 m3/day from the Boundary Dam amine processing unit as a basis for economic analysis, a total capital investment of $216,981.69 was estimated. It was projected that an annual operating cost of $513,884.85 will be required to run the photocatalytic waste treatment plant at a treatment cost of $10.59/m3. This study presents a foundation for future research into the scale up and eventual commercialization of this wastewater treatment technique.
Author: Elvis Fosso-Kankeu
Publisher: John Wiley & Sons
ISBN: 1119631440
Category : Science
Languages : en
Pages : 320
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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: Sadanand Pandey
Publisher: John Wiley & Sons
ISBN: 1394197888
Category : Technology & Engineering
Languages : en
Pages : 237
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Book Description
The concept of photoelectrochemistry applied to microbial fuel cells could be the future of sustainable wastewater treatment and for hydrogen recovery as a valuable energy source. With the increase of recalcitrant organic pollutants in industrial wastewater, the need for a sustainable bio-electrochemical process has become pressing in order to ensure that treatment processes are coupled with some beneficiation advantages. Microbial fuel cells combine wastewater treatment and biological power generation. However, the resistance of these organic pollutants to biological degradation requires further adjustment of the system to improve sustainability through maximization of energy production. Solar energy conversion using photocatalysis has drawn huge attention for its potential to provide renewable and sustainable energy. Furthermore, it might be the solution to serious environmental and energy-related problems. It has been widely understood for several years that the top global issues today are concerned with securing a clean supply of water and ensuring a reasonable price for clean energy. Researchers are studying advanced materials and processes to produce clean, renewable hydrogen fuel through photocatalytic and photoelectrocatalytic water splitting, as well as to reduce carbon dioxide from the air into fuels through photocatalysis. Limited progress is occurring in these areas. The purpose of this book is to comprehensively cover the evolvement in the conceptualization and application of photocatalytic fuel cells, as well as make a critical assessment of the contribution in the field of sustainable wastewater treatment and renewable energy production. This book contains nine specialized chapters that provide comprehensive coverage of the design of photocatalytic fuel cells and their applications, including environmental remediation, chemical synthesis, green energy generation, model simulation for scaling up processes and implementation, and most importantly maximization of hydrogen evolution, recovery, and applications. Audience A wide audience of academics, industrial researchers, and graduate students working in heterogeneous photocatalysis, fuel cells, sustainable chemistry, nanotechnology, chemical engineering, environmental protection, and surfaces and interfaces, will find this book useful. The book is also important for professionals, namely environmental managers, water treatment plants managers and operators, water authorities, government regulatory bodies officers, and environmentalists.
Author: Enrico Mendes Saggioro
Publisher:
ISBN:
Category : Technology
Languages : en
Pages :
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Book Description
Organic dyes constitute one of the largest groups of wastewater's pollutants. In general, they are released into the environment by textile industries. Approximately 100,000 dyes are widely used in the textile industry, and a large wastewater of dyestuff is generated annually. Among these, indigoid class is commercial dyes used mostly for cotton cloth dyeing. Indigo carmine (IC) is also one of the oldest dyes and still one of the most used in textile industry and is considered as a very toxic indigoid dye. Most toxic dyes are recalcitrant to biodegradation, causing a decrease in the efficiency of biological wastewater treatment plants. Titanium dioxide is a well-known photocatalyst mostly used in suspensions in photoreactions for wastewater treatment. The use of TiO2 has some advantages such as ease of handling, low cost, low toxicity, high photochemical reactivity, and non-specific oxidative attack ability. In this way, it can promote the degradation of different target organic compounds with little change of operational parameters. The aim of this chapter is to present the different approaches already used in our team for the remediation of waters containing IC mainly through heterogeneous photocatalysis with TiO2. Adsorption over activated carbon (AC) and photocatalytic degradation of IC mediated by titanium dioxide will be revised as well as some studies on the phototoxicity of the photoproducts with aquatic and terrestrial organisms. This chapter makes a comprehensive approach to the different results on the remediation of model effluents containing IC undertaken by this team of researchers.
Author: Inamuddin
Publisher: Springer Nature
ISBN: 303054723X
Category : Science
Languages : en
Pages : 443
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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: David Reay
Publisher: Butterworth-Heinemann
ISBN: 0080983057
Category : Technology & Engineering
Languages : en
Pages : 624
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Book Description
Process Intensification: Engineering for Efficiency, Sustainability and Flexibility is the first book to provide a practical working guide to understanding process intensification (PI) and developing successful PI solutions and applications in chemical process, civil, environmental, energy, pharmaceutical, biological, and biochemical systems. Process intensification is a chemical and process design approach that leads to substantially smaller, cleaner, safer, and more energy efficient process technology. It improves process flexibility, product quality, speed to market and inherent safety, with a reduced environmental footprint. This book represents a valuable resource for engineers working with leading-edge process technologies, and those involved research and development of chemical, process, environmental, pharmaceutical, and bioscience systems. - No other reference covers both the technology and application of PI, addressing fundamentals, industry applications, and including a development and implementation guide - Covers hot and high growth topics, including emission prevention, sustainable design, and pinch analysis - World-class authors: Colin Ramshaw pioneered PI at ICI and is widely credited as the father of the technology
Author: Sarah M. Mercer
Publisher:
ISBN:
Category : Photocatalysis
Languages : en
Pages : 162
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Book Description
Author: Jennifer Wilcox
Publisher: Springer Science & Business Media
ISBN: 1461422140
Category : Science
Languages : en
Pages : 337
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Book Description
This book approaches the energy science sub-field carbon capture with an interdisciplinary discussion based upon fundamental chemical concepts ranging from thermodynamics, combustion, kinetics, mass transfer, material properties, and the relationship between the chemistry and process of carbon capture technologies. Energy science itself is a broad field that spans many disciplines -- policy, mathematics, physical chemistry, chemical engineering, geology, materials science and mineralogy -- and the author has selected the material, as well as end-of-chapter problems and policy discussions, that provide the necessary tools to interested students.
Author: Jose Ricardo Alvarez Corena
Publisher:
ISBN:
Category :
Languages : en
Pages : 252
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Book Description
Abstract: The simultaneous degradation of five organic contaminants: 1,4 dioxane, n-nitrosodimethylamine, tris-2-chloroethyl phosphate, gemfibrozil, and 17[beta] estradiol, was investigated using a 1 L batch water-jacketed UV photoreactor utilizing titanium dioxide (TiO2) nanoparticles (Degussa P-25) as a photocatalyst. The primary objectives of this research were: (1) to experimentally assess the feasibility of heterogeneous photocatalysis as a promising alternative for the degradation of organic compounds in water; and (2) to model the chemical reactions by the application of two different approaches based on adsorption -- surface reactions (Langmuir-Hinshelwood) and its simplification to a first order rate reaction. These objectives were motivated by the lack of information regarding simultaneous degradation of organic compounds in different categories as found in real aqueous matrices, and generation of specific intermediates that could eventually represent a potential risk to the environment. Contaminants were chosen based on their occurrence in water sources, their representativeness of individual sub-categories, and their importance as part of the CCL3 as potential contaminants to be regulated. Contaminant degradation was evaluated over time, and the TiO2 concentration and solution pH were varied under constant UV irradiation, oxygen delivery rate, mixing gradient, and temperature. Specific accomplishments of this study were: (1) reaction kinetics data were obtained from the UV/TiO2 experiments and showed the potential that this UV/TiO2 process has for effectively removing different types of organic compounds from water; (2) a good fit was obtained between photocatalytic reaction kinetics models and the contaminant data using pseudo first-order and Langmuir-Hinshelwood (L-H) models; (3) results of the analytical methods developed in this study were validated by measurements performed by a certified laboratory; (4) the reaction kinetic parameters obtained in this study were normalized to electrical energy per order, reactor volume and surface area of the photocatalyst in order to provide rate constants with wider applicability for scale-up to more complex systems; and (5) degradation intermediates from the oxidation process and from interaction among compounds were identified and possible pathways for their formation suggested. This research has provided a better understanding of the photocatalytic process for the removal of organic contaminants from complex aqueous matrices.
