Drinking Water Disinfection Byproduct Formation Assessment Using Natural Organic Matter Fractionation and Excitation-emission Matrices
Drinking Water Disinfection Byproduct Formation Assessment Using Natural Organic Matter Fractionation and Excitation-emission Matrices

Author: David W. Johnstone

Publisher:

Published: 2009

Total Pages: 184

ISBN-13:

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"Disinfection byproducts (DBP) pose a major problem for the drinking water industry due to their carcinogenic nature and formation when natural organic matter (NOM) reacts with chlorine. This study investigates the formation of individual DBP compounds within waters containing various NOM characteristics. Water from the Iowa River was concentrated through reverse osmosis and NOM fractions were isolated using resin separation. In addition, waters from the city of Barberton water treatment plant were collected prior to and subsequent to coagulation. Experiments were conducted on each water source under variable chlorine doses and pH, with and without the presence of model iron oxides. The purpose of this study was to investigate the role of NOM and the surrounding environment on DBP formation and develop measures for the prediction of byproduct formation. Fluorescence excitation-emission matrices (EEM) of NOM were quantified and characterized using fluorescence regional integration (FRI) and parallel factor analysis (PARAFAC). Changes in FRI of five operationally defined regions coupled with chlorine consumption showed strong linear relationships to the formation of chloroform (CHCl3), dichloroacetic acid (Cl2AA), and trichloroacetic acid (Cl3AA). Stepwise regression of fluorescence regions revealed the use of only one region coupled with chlorine consumption to predict DBP formation, yet this region varied depending upon the individual compound assessed. This technique provides an effective tool that can utilize both chlorine reactivity and functional group properties of the NOM to predict DBP formation. PARAFAC analysis of EEM yielded three statistically significant components providing relative concentrations of fluorophores within each sample. While this technique has previously been used for NOM characterization, it has yet to be utilized to assess DBP formation. Multi-factor linear regression of select component scores showed strong linear relationships to individual DBP compounds providing insight to organic compound characteristics responsible for DBP formation. These finding suggest that fluorophore component scores may be an effective parameter used to estimate DBP precursor concentration. In doing so, water plants can evaluate the fluorescence components and assess the effects of various treatment schemes on NOM, providing a more specific approach to precursor removal and a better understanding of DBP formation."--Abstract.

Natural Organic Matter and Disinfection By-products Characterization and Control in Drinking Water
Natural Organic Matter and Disinfection By-products Characterization and Control in Drinking Water

Author: Sylvia E. Barrett

Publisher:

Published: 2000

Total Pages: 448

ISBN-13:

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There are many by-products of water disinfection that are still not fully understood and can be potentially harmful. In this volume all the current research in this area is discussed, along with an examination of the role of NOM (natural organic matter) and its relationship to DBP (disinfection by-product) formation and control in drinking water. Understanding the relationship of NOM to DBP may well lead to new techniques for analyzing and treating water and enable reasonable choices to be made for source-water protection, treatment plant process optimization, and distribution system operation to control DBP's. This volume emphasizes the characterization and reactivity of polar natural organic matter. It examines analytical methods which better characterize NOM and determines some of the polar and nonvolatile DBP forms. It presents innovative new methods, sich as capillary electrophoresis for haloacetic aceids and LC/MS for the identification of polar dinking water DBPs.

New Insights Into Disinfection Byproduct Formation and Control
New Insights Into Disinfection Byproduct Formation and Control

Author: Ashley Dale Pifer

Publisher:

Published: 2012

Total Pages: 310

ISBN-13: 9781267550095

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Methods were developed for application of asymmetric flow field-flow fractionation (AF4) and fluorescence parallel factor (PARAFAC) analysis to raw and treated samples from drinking water sources to improve characterizations of dissolved organic matter (DOM) and discover DOM properties correlated to disinfection byproduct (DBP) formation potential (FP). Raw water samples were collected from a reservoir, adjusted to pH 6, 7, and 8 and subjected to (1) jar tests using aluminum sulfate (alum) and (2) treatment with magnetic ion exchange (MIEX®) resin. Both treatments were followed by DBPFP tests at pH 7. AF4 was used to size DOM in raw and alum treated samples at pH 6 and 8. AF4 fractograms showed that DOM removal was more effective at pH 6 than at pH 8, and preferential removal of larger-sized DOM occurred at pH 6 but not at pH 8. A fluorescence-PARAFAC model was constructed using excitation-emission matrices (EEMs) from all samples. A strong linear correlation (r 2 = 0.87) between chloroform FP and a humic-like PARAFAC component (C1) was developed. This correlation was a significant improvement over the correlation (r 2 = 0.03) between chloroform FP and specific ultraviolet absorbance at 254 nm (SUVA254), a DBPFP surrogate commonly used in drinking water treatment plants to optimize DOM removal processes. This indicated that chloroform FP-C1 correlations were not treatment-specific. Alum coagulation at pH 6, 7, and 8 and DBPFP tests at pH 7 were performed on a set of raw waters from eleven drinking water treatment plants from across the United States. AF4 was used to size DOM before and after alum coagulation, and showed similar results to the earlier study, i.e., increased removal at pH 6 compared to pH 8. A fluorescence-PARAFAC model was constructed and total trihalomethane (TTHM) FP was strongly correlated (r 2 = 0.91) to C1 for eight water sources. TTHMFP-SUVA254 correlations for ten locations were weak (r 2 = 0.15), which indicated that C1 was an improved DBPFP surrogate relative to SUVA254 and could be used as a surrogate to select and optimize DBP precursor removal processes.

Disinfection By-products in Drinking Water
Disinfection By-products in Drinking Water

Author: K Clive Thompson

Publisher: Royal Society of Chemistry

Published: 2015-09-29

Total Pages: 368

ISBN-13: 1782622713

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Covering the latest developments in themes related to water disinfection by-products, this book brings the reader right up to date. Stemming from an international conference, contributions are from decision-makers, regulators and the relevant scientific community. Coverage includes emerging disinfection by-products, water treatment, water recycling, monitoring, regulation and health and toxicology aspects. It will be of interest to water companies, public health professionals, drinking water quality regulators, suppliers of laboratory and on-line monitoring equipment, analytical chemists, and academic and industry researchers working in the area of disinfection by-products.

Disinfection Byproducts in Drinking Water
Disinfection Byproducts in Drinking Water

Author: Yuefeng Xie

Publisher: CRC Press

Published: 2003-08-27

Total Pages: 180

ISBN-13: 0203486919

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The EPA has established regulations which classify four types of disinfection byproducts - TTHMs, haloacetic acids, bromate, and chlorite - and requires public water systems limit these byproducts to specific levels. Most of the information required to comply with these standards is either scattered throughout the literature or derived from confere

Disinfection By-products in Drinking Water
Disinfection By-products in Drinking Water

Author: M.N.V. Prasad

Publisher: Butterworth-Heinemann

Published: 2020-02-18

Total Pages: 492

ISBN-13: 0081029780

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Disinfection Byproducts in Drinking Water: Detection and Treatment presents cutting-edge research on how to understand the procedures, processes and considerations for detecting and treating disinfection by-products from drinking water, swimming pool water, and wastewater. The book begins with an overview of the different groups of Disinfection Byproducts (DBPs), such as: Trihalomethanes (THM), Halo acetic acids, and Haloacetonitrile (HAN). This coverage is quickly followed by a clear and rigorous exposition of the latest methods and technologies for the characterization, occurrence, formation, transformation and removal of DBPs in drinking water. Other chapters focus on ultraviolet-visible spectroscopy, electron spin resonance, and gas chromatography-mass spectrometry. Researchers will find a valuable resource to a breath of topics for DBP detection and treatment, including various recent techniques, such as microfiltration, nanofiltration membrane and nanotechnology. Explains the latest research in detection, treatment processes and remediation technologies Includes sampling, analytical and characterization methods and approaches Covers cutting-edge research, including membrane based technologies, nanotechnology treatment technologies and bioremediation treatment technologies Provides background information regarding contamination sources

Aquatic Organic Matter Fluorescence
Aquatic Organic Matter Fluorescence

Author: Paula G. Coble

Publisher: Cambridge University Press

Published: 2014-07-14

Total Pages: 407

ISBN-13: 0521764610

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A core text on principles, laboratory/field methodologies, and data interpretation for fluorescence applications in aquatic science, for advanced students and researchers.

Analysis and Formation of Disinfection Byproducts in Drinking Water
Analysis and Formation of Disinfection Byproducts in Drinking Water

Author: Tarek Manasfi

Publisher: Elsevier

Published: 2021-03-31

Total Pages: 174

ISBN-13: 0444643435

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Drinking water disinfection has markedly reduced diseases causes by waterborne pathogenic microorganisms. However, an unintended consequence of disinfection and/or oxidation processes is the generation of disinfection byproducts (DBPs) which are formed from the reactions of disinfectants/oxidants with water matrix components. This volume of the Comprehensive Analytical Chemistry Handbook presents recent advances about the formation, identification, and quantification of inorganic and organic DBPs during oxidative processes. The book begins with a first chapter reviewing the most recent non-targeted screening approaches and workflows to characterize DBPs using low-, high-, and ultra-high-resolution mass spectrometry. The second chapter discusses the analysis of inorganic chloramines in waters using on-site and/or in-lab analytical methods. The third chapter provides an overview of the current knowledge about the mechanisms of chlorine dioxide reactions and byproducts formation. The fourth chapter presents some fundamental and practical aspects about ozonation processes in water treatment and provides an overview about ozone reaction mechanisms and byproducts formation. The fifth chapter focuses on the reactivity of halide ions, particularly bromide and iodide, with common oxidants and the role they play in determining the speciation of DBPs in treated waters. The chapter also presents strategies to mitigate the formation of DBPs during oxidation processes. Finally, the last chapter tackles the topic of DBPs formation during potable water reuse. It discusses the formation of DBPs of major concern in both memebrane-based and non-membrane-based potable water reuse treatment schemes. Researchers, water treatment specialists, and regulators will find in this book a valuable and compact resource on several key topics regarding the formation, identification, quantification, and mitigation of DBPs. Identification and quantification of known and unknown DBPs Formation of DBPs during different disinfection/oxidation processes DBPs of concern in new technologies and/or new applications of existing technologies in water treatment

Fate of Natural Organic Matter and Formation of Disinfection By-products in a Conventional Water Treatment Plant
Fate of Natural Organic Matter and Formation of Disinfection By-products in a Conventional Water Treatment Plant

Author: Noha Hesham Abdel Halim

Publisher:

Published: 2014

Total Pages: 146

ISBN-13:

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Abstract: Elevated levels of disinfection by-products (DBPs), detected in Cairo residential water supply during the past decade, were the motivation to study the process of DBP formation at the water treatment plant (WTP) stage. It is hoped that an in-depth understanding of natural organic matter (NOM) characteristics and DBP formation/removal in an existing WTP will yield a baseline as well as insights for the development of optimum strategies for cost-effective reduction of potentially harmful drinking water compounds such as Trihalomethanes (THMs) and Haloacetic acid (HAAs). The objectives of this research were to: investigate the degree of removal of the various NOM fractions in conventional WTPs and identify the factors that may possibly enhance their removal; and investigate the levels of formed DBPs within conventional WTPs when pre-chlorination and post-chlorination are applied. Water samples were collected from El-Fustat WTP in Cairo from 4 different points along the treatment process and covering the four different seasons of a year. NOM was quantified by classical surrogate parameters such as total organic carbon (TOC), dissolved organic carbon (DOC), and ultraviolet absorbance (UVA254); and characterized more precisely according to its hydrophobic-hydrophilic properties using resin fractionation. THMs, HAAs and other water quality analyses were conducted for all collected samples. Measurements of NOM fractions following each treatment unit indicate that the hydrophobic fraction is significantly removed by the coagulation/flocculation/ sedimentation processes (56% to 13% in the various seasons) whereas the transphilic, and hydrophilic fractions were removed to much lower degree (51% to 10%) and (15% to 4%), respectively. The hydrophobic fraction had formed flocs with the added alum more than the other two fractions. No further removal of NOM takes place in rapid sand filtration or post-chlorination units. Although the THMs values recorded for the entire study were complying with the Egyptian guidelines, it is not guaranteed that tap concentrations will comply to the guidelines limits. This is because THM/THMFP does not exceed 39%, leaving room for 61% to be reacted in pipe lines and storage tanks until it reaches the customers taps. In addition, HAAs concentrations at the plant effluent were much higher than the regulating limits, alarming the WTP to exert more effort to reduce THMs, and HAAs values. On an attempt to identify the relative importance of NOM fractions in THMs formation, the measured values of the THMs were regressed to each NOM fraction and the coefficient of determination (R2) was calculated. Results showed that unlike hydrophobic fraction and transphilic fractions (R2 = 0.01, 0.14), respectively, hydrophilic NOM fractions are consistently most responsible for THM and HAAs production at the plant effluent (R2 = 0.77, 0.62. Although, hydrophilic fraction was the main contributor to THMs and HAAs formation in El-Fustat WTP; coagulation/flocculation and sedimentation could not successfully remove it during treatment. Accordingly, the processes of coagulation/flocculation/sedimentation/filtration are not guaranteed to be useful in decreasing the DBPs levels. El-Fustat WTP does not technically implement "Enhanced Coagulation"; however, initial results from this study shows that the hydrophillic DOC fraction is less likely to be removed during Enhanced Coagulation but the major DOC contributor to DBPs formation. Future work should test this hypothesis through a bigger and wider sample size. Free chlorine concentrations are responsible for the high THM levels at the plant effluent, which implies its responsibility on THMs formed in the plant and the formation potential in distribution pipelines. Therefore, reducing the chlorine doses as much as possible to reach zero free chlorine before post-chlorination and the minimum acceptable free chlorine residual for secondary disinfection is going to reduce the THMs and HAAs levels substantially.

The Effect of Natural Organic Matter Variation and Pipe Deposit Material on Disinfection Byproduct Formation
The Effect of Natural Organic Matter Variation and Pipe Deposit Material on Disinfection Byproduct Formation

Author: Nicholas Golden

Publisher:

Published: 2005

Total Pages: 208

ISBN-13:

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"Disinfection byproduct (DBP) formation bottle tests were performed on municipally treated drinking water samples obtained during the period from 9/15/03 to 11/24/03 with samples being taken post-filtration but before final chlorination from the City of Akron water treatment plant. Samples were chlorinated under two conditions in small amber bottles; aqueous-only system and in the presence of powdered goethite, a representative pipe deposit material, under the same pH and initial chlorine dose. The natural organic matter (NOM) in each of the water samples was analyzed for initial values of TOC, UV254, SUVA, and six relative fluorescence fractions and for the six relative fluorescence fractions after adsorption equilibrium with the powdered goethite. Disinfection byproduct formation was then correlated to these natural organic matter measurements. The NOM measurements were shown to vary, sometimes greatly, even within very short sampling periods suggesting that the nature and reactivity of the NOM can fluctuate over relatively short periods of time. TOC, UV254, and SUVA values did not correlate well with DBP formation, individually. The six relative fluorescence fractions when used along with SUVA correlated well with DBP formation for the aqueous-only system and were correlated well with trihalomethane (THM) formation for the goethite system. Disinfection byproduct formation was impacted greatly with the presence of the representative pipe deposit material, goethite. Average increases of 44 ppb, 39 ppb, and 40 ppb were found for total DBP, total THM, and chloroform formation with the goethite system having a much greater efficiency of DBP formation with equal amounts of TOC as the aqueous-only system. The goethite also impacted speciation of the THM and haloacetic acids (HAA) with the goethite system showing large increases in chloroform with little changes in bromodichloromethane (BDCM) formation. HAA species also changed significantly with the majority of the sample waters showing an increase in dichloroacetic acid (DCAA) and a decrease in trichloroacetic acid (TCAA) yielding little to no change in total HAA formation. Correlation of HAA formation with NOM measurements yielded little results possibly due to competitive degradation reactions of TCAA and DCAA."--Abstract.