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Kinetic Analysis of Haloacetonitrile Stability in Drinking Waters Yun Yu, and David A. Reckhow Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.5b02772 • Publication Date (Web): 14 Aug 2015 Downloaded from http://pubs.acs.org on August 24, 2015

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Kinetic Analysis of Haloacetonitrile Stability in Drinking Waters

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Authors: Yun Yu*1, David A. Reckhow2

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1. PhD Candidate, 18 Marston Hall, 130 Natural Resources Rd., Dept. of Civil and Environmental

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Engineering, University of Massachusetts Amherst, Amherst, MA, 01003-9293. E-mail:

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[email protected] Phone: 413-362-4918 (Corresponding Author).

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2. Professor, 18 Marston Hall, 130 Natural Resources Rd., Dept. of Civil and Environmental Engineering, University of Massachusetts Amherst, Amherst, MA 01003-9293. E-mail: [email protected]. Phone: 413-545-5392

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ABSTRACT Haloacetonitriles (HANs) are an important class of drinking water disinfection byproducts (DBPs)

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that are reactive and can undergo considerable transformation on time scales relevant to system

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distribution (i.e., from a few hours to a week or more). The stability of seven mono-, di- and

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trihaloacetonitriles was examined under a variety of conditions including different pH levels and

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disinfectant doses that are typical of drinking water distribution systems. Results indicated that hydroxide,

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hypochlorite, and their protonated forms could react with HANs via nucleophilic attacks on the nitrile

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carbon, forming the corresponding haloacetamides (HAMs) and haloacetic acids (HAAs) as major

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reaction intermediates and end products, respectively. Other stable intermediate products, such as the N-

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chloro-haloacetamides (N-Cl-HAMs) may form during the course of HAN chlorination. A scheme of

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pathways for the HAN reactions was proposed and the rate constants for individual reactions were

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estimated. Under slightly basic conditions, hydroxide and hypochlorite are primary reactants and their

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associated second-order reaction rate constants were estimated to be 6 to 9 orders of magnitude higher

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than those of their protonated conjugates (i.e., neutral water and hypochlorous acid), which are much

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weaker but more predominant nucleophiles at neutral and acidic pHs. Developed using the estimated

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reaction rate constants, the linear free energy relationships (LFERs) summarized the nucleophilic nature

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of HAN reactions and demonstrated an activating effect of the electron withdrawing halogens on nitrile

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reactivity, leading to decreasing HAN stability with increasing degree of halogenation of the substituents,

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while subsequent shift from chlorine to bromine atoms has a contrary stabilizing effect on HANs. The

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chemical kinetic model together with the reaction rate constants that were determined in this work can be

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used for quantitative predictions of HAN concentrations depending on pH and free chlorine contact times

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(CTs), which can be applied as an informative tool by drinking water treatment and system management

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engineers to better control these emerging nitrogenous DBPs, and can also be significant in a regulatory

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context.

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INTRODUCTION The presence of halogenated nitrogenous disinfection byproducts (N-DBPs) in drinking

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waters, including haloacetonitriles (HANs) and haloacetamides (HAMs), is of increasing concern

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to the public health due to their substantially higher cytotoxic and genotoxic potencies as well as

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greater developmental toxicity than the currently regulated DBPs.1-5 Haloacetonitriles (HANs) are

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an important class of N-DBPs that are nearly ubiquitous in drinking waters, with the total mass

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typically representing approximately 10% of the trihalomethanes (THMs).6,7 Regardless of their

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relatively low occurrence, the significance of HANs as emerging N-DBPs is offset by their

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perceived high cytotoxicity and genotoxicity, which are up to two orders of magnitude greater

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than those of the regulated haloacetic acids (HAAs).1 HANs were first identified in US tap water

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in 19758 and their formation can be attributed to the chlorination or chloramination of free amino

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acids,9-12 combined amino acids that are bound to humic structures,7,10 and to a lesser extent,

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heterocyclic nitrogen in nucleic acids.12,13 Simultaneous to the discovery of HANs, it was noticed

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that this group of compounds was absent in finished waters with high pHs.9,14 It was revealed by

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subsequent studies that HANs are metastable and can undergo considerable degradation through

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neutral and base-catalyzed hydrolysis on time scales relevant to distribution system residence

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times,17 and the hydrolysis rates increase with increasing pH.9,14-17

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In addition to pH as an important facilitator, the presence of chlorine is also known to have an

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accelerating effect on the rate of loss for dihaloacetonitriles (DHANs).7 Compared to the

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hydrolysis rate of dichloroacetonitrile (DCAN), its accelerated rate of loss in the presence of

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chlorine indicates the existence of certain independent chlorination pathways.16,17 Peters and co-

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workers16 proposed that DCAN reacts with chlorine through either direct addition of HOCl onto

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the cyano group or through hypochlorite catalyzed hydrolysis, and both pathways lead to the

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formation of dichloroacetamide (DCAM), N-chloro-dichloroacetamide (N-chloro-DCAM) as

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reaction intermediates, and dichloroacetic acid (DCAA) as final product. Since it is a common 4 ACS Paragon Plus Environment

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practice for drinking water systems to maintain at least 0.2 mg/L free chlorine residual throughout

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distribution, and concentrations near the point of entry can be as high as 2 mg/L, it is crucial to

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understand the impact of chlorine on the stability of a more complete set of HANs, especially the

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brominated species. Furthermore, the formation and lifetime of the intermediate products have

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not been assessed and reconciled with the prevailing reaction pathways.

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On the other hand, there are a large number of US drinking water utilities that have switched

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from free to combined chlorine, particularly chloramines, to minimize the formation of THMs

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and HAAs,18 as regulations for these two groups of DBPs are becoming more and more stringent

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(e.g., the Stage II Disinfectants/Disinfection Byproducts Rule). In addition to the regulatory

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drivers, there are concerns that chloramines could otherwise enhance the formation of N-DBPs,

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because the nitrogen incorporated in those N-DBPs can be derived either from the organic

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precursors, or in the case of chloramination, from the disinfectant.19 Based on the collected data

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required by the Information Collection Rule (ICR), a higher level of total HANs (i.e., DCAN,

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BCAN, DBAN and TCAN) was detected in large US surface water plants that used chloramines

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(both with and without chlorine) than those that only used chlorine.20 However, such elevated

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HAN occurrence may be attributable to the higher level of precursors in the source water, and not

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necessarily to an inherent tendency of chloramines to form more HANs.20 In fact, laboratory

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research has shown a higher formation potential of DCAN during free chlorination than during

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chloramination regardless whether chloramines were pre-formed or formed in-situ.21 It is

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noteworthy that the stability of HANs under conditions that are typical of those used by systems

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practicing chloramination has not been reported to clarify whether the relatively higher

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occurrence of HANs is due to their greater stability in the presence of chloramines or to the

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higher tendency of chloramines in the formation of HANs as an additional nitrogen source.

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Despite the general understanding that HANs actively transform into secondary byproducts under a wide range of pH conditions with and without the presence of chlorine, most of the

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previous work is focused on DHANs, especially on DCAN as the most prevalent HAN

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species.7,9,14,17 Moreover, the second-order reaction rate constants with regard to relevant drinking

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water constituents (e.g., hydroxide, free chlorine, etc.) have not been systematically reported or

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determined for most HANs, the corresponding reaction mechanisms have not been elucidated,

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and intermediate reaction products have not been quantified and reconciled with the prevailing

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reaction pathways. For these reasons, a more comprehensive kinetic analysis is necessary to

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understand the reaction kinetics, pathways, and products for the other monohalogenated,

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trihalogenated, and particularly the brominated HANs, considering that the brominated DBPs are

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demonstrated to be more toxic than their chlorinated analogs.3 Perhaps most importantly, kinetic-

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based decomposition models have not been developed for most of the chlorinated and brominated

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HANs to adequately characterize their reactions and to allow for quantitative estimation of their

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concentrations in drinking water distribution systems based on pH and chlorine residual as two

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predominant influencing factors.

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The purpose of this study was to evaluate the chemical stability of a more complete set of

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HANs under a wide range of pH conditions (i.e., pH 6-9) with and without disinfectant doses (i.e.,

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free chlorine and chloramines), and to obtain a fundamental understanding of HAN reaction

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mechanisms as well as the nature of consequent reaction products. Another key objective of this

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investigation was to quantitatively characterize HAN reactions by developing a mathematical

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kinetic model and determining the corresponding rate constants for individual HAN reactions.

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The resulting model can be used in quantitative predictions of HAN temporal concentration

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profiles in drinking water distribution systems with or without simple modifications depending on

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the dynamics of chlorine residual.

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MATERIALS AND METHODS Chemicals

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Unless otherwise noted, all chemicals were purchased from Fisher Scientific Co. and were of

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analytical grade. Purified DBP standard compounds including monochloroacetonitrile (MCAN),

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monobromoacetonitrile (MBAN), dichloroacetonitrile (DCAN) and trichloroacetonitrile (TCAN)

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were purchased from Sigma-Aldrich. Bromochloroacetonitrile (BCAN) and dibromoacetonitrile

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(DBAN) were supplied by Crescent Chemical. Bromodichloroacetonitrile (BDCAN) and three of

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the brominated HAMs were synthesized by CanSyn Chem. Corp. in Canada. The haloacetic acids

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mix was obtained from Sigma-Aldrich. Sources and purities of all the standard compounds are

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available in Table S1.

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Experimental Conditions

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All solutions were prepared in ultra-pure Milli-Q water (EMD Millipore Corp.) containing 10

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mM phosphate buffer and were adjusted to the desired pH with sodium hydroxide or hydrochloric

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acid. One milliliter of mixed HAN stock solution (1 mg/mL in methanol) was introduced into 4 L

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buffered solutions at the start of each experiment, so that the initial concentration for individual

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HANs was approximately 250 µg/L. Chlorination of HANs was conducted by adding small

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volumes of acidified sodium hypochlorite stock solution (5.65-6%, pH 5.2) to reach the target

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doses, prior to which, the actual concentration of the chlorine stock was standardized using the

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DPD-FAS titrimetric method (EPA Method 330.4). Chloramination was carried out by adding

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small amounts of a 40 mM chloramine stock solution to each sample, and the chloramines were

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pre-formed by mixing aqueous ammonium sulfate and sodium hypochlorite at a Cl2/N ratio of 0.8

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M/M, with pH of both solutions adjusted to 8.5 before mixing. After dosing with chlorine or

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chloramines, samples were partitioned off into 300 mL BOD bottles and were stored headspace-

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free in a dark 20℃ constant temperature chamber for a maximum of 19 days. At the prescribed

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reaction times, one bottle of sample would be sacrificed and analyzed immediately for

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disinfectant residual and DBP concentrations. Six sample replicates were analyzed in this study

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for the estimation of measurement uncertainties. 7 ACS Paragon Plus Environment

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Sample Preparation and Chromatographic Analysis

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The extraction and analysis of HANs was based on EPA Method 551.1. After the prescribed

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reaction time, 20 mL aliquots of sample were first acidified using 100 µL of 6N hydrochloric acid.

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In the case of chlorination and chloramination of HANs, residual oxidant was quenched by 20

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mg/L ascorbic acid after sample acidification. HANs were extracted by adding 4 mL of pentane

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with an internal standard (1,2-dibromopropane) into each sample, together with 15 g of

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anhydrous sodium sulfate. The samples were shaken at 300 rpm for 15 minutes and the upper

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organic layer was collected for chromatographic analysis. Haloacetic acids were quantified

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following the EPA 552.2 method. The standard operating procedures include pH adjustment and

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quenching of the disinfectant residual, acidification of 30 mL sample using 1.5 mL of 95.0-98.0%

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W/W sulfuric acid, and extraction with methyl tert-butyl ether, followed by methylation using 5%

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acidic methanol. Analysis of the HAMs was conducted via a solid-phase extraction/gas

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chromatography-mass spectrometry (SPE/GC-MS) method that was developed by the authors for

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this study (Yu & Reckhow, unpublished method). The SPE procedure involves initial

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conditioning of the extraction cartridges (Bond Elut PPL, 200 mg, 3 mL, Agilent Technologies)

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using 9 mL of methanol followed by 6 mL of Milli-Q water, sample loading (100 mL at ~2

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mL/min), nitrogen drying of the cartridges for 30 minutes, and final elution with 2 mL of ethyl

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acetate. HANs and the derivatized methyl haloacetates were analyzed using an Agilent 6980 gas

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chromatography with a linearized micro-electron capture detector (µ-ECD). HAMs were

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separated and detected by a Varian CP-3800 gas chromatography coupled with a Varian Saturn

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2200 ion-trap mass spectrometer using chemical ionization. Detailed information about the

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capillary GC columns and oven temperature programs are provided in Table S2.

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RESULTS AND DISCUSSION

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Hydrolysis of Haloacetonitriles

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The hydrolysis of seven HANs (MCAN, MBAN, DCAN, BCAN, DBAN, TCAN and

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BDCAN) was investigated at pH 6, 7, 8, 8.5, and 9 in phosphate buffered solutions for reaction

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times of a few minutes to a total of 19 days (456 hours). Residual HAN concentrations were

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consistent with a rate law that is first-order in HANs (Figure 1). All seven HANs are most stable

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at pH 6 and the rate of loss increases with both increasing pH and the number of halogens, which

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is in general agreement with previous observations regarding HAN hydrolytic stability.7,9,15,17 The

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instantaneous hydrolysis of trihaloacetonitriles (THANs) even under slightly acidic and neutral

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pH conditions (i.e., pH 6-7) explains their overall absence in most drinking water systems as

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noted from the ICR database.20 In sharp contrast, concentrations of the monohalogenated

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acetonitriles (MHANs) remained nearly constant during the entire period of the hydrolysis

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experiment regardless of pH (Figure S1). Furthermore, with the same number of halogens in the

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substituents, HAN hydrolysis rate decreased as the halogens shifted from chlorine to bromine,

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resulting in the following hierarchy of HAN hydrolytic stability:

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MBAN>MCAN>DBAN>BCAN>DCAN>BDCAN>TCAN.

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Figure 1. Semi-logarithmic plots of residual HAN concentrations versus reaction time under five

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hydrolysis pH conditions.

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To verify the prevailing HAN hydrolysis pathways,17 two putative intermediates (i.e., HAM

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and HAA) were quantified during the course of HAN hydrolysis. In general, results demonstrated

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that the loss of HANs was accompanied by a rapid increase in the corresponding HAM 9 ACS Paragon Plus Environment

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concentrations, followed by a slower formation of the HAAs. Unlike the HAAs, HAMs are

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metastable intermediates and are also subject to possible hydrolysis depending on pH and the

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number of halogens in the substituent (Yu & Reckhow, unpublished work). Figure 2 shows the

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formation of DCAM (and TCAM) and DCAA (and TCAA) during DCAN (and TCAN)

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hydrolysis under four different pH conditions. It is obvious in Figure 2 that DCAM tended to

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hydrolyze when pH was above 8, causing its concentration to first increase and then decrease at

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pH 9. Compared to DCAM, TCAM started to hydrolyze at a lower pH (i.e., pH 8) due to the

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higher degree of halogenation, and its concentration profile was characterized by a distinct peak

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at pH 8 and only by its decomposition at pH 9. In spite of the temporal changes in individual DBP

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concentrations, the molar sum of the three HAN, HAM and HAA species remained constant over

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reaction time for all the hydrolysis experiments, and this mass balance substantiates the previous

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hypothesis that hydrolysis of HANs only produces HAMs and HAAs as major reaction

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products.15,17

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Figure 2. Intermediates formation during the course of DCAN (top row) and TCAN (bottom row)

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hydrolysis .The dashed lines represent the initial DCAN and TCAN molar concentrations spiked

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at the beginning of each experiment.

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Based on the 1st-order HAN kinetics that is evident in Figure 1, the full 2nd-order hydrolysis rate law is proposed to be the following:  = −  ∙  = − ∙  −  ∙    (. 1) 

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In the above equation, kH2O and kOH are the neutral and basic hydrolysis rate constants,

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respectively. Although it has been acknowledged that neutral water is about nine orders of

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magnitude less reactive to HANs than the anionic hydroxide,17 the neutral hydrolysis rate

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constant (i.e.,  ) and the product of    can be similar in magnitude, and thus equally

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contributing to the hydrolysis rate of HAN when pH is below or close to 5. For this reason, the

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proposal of a neutral hydrolysis pathway and the estimation of the corresponding reaction rate

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constant (i.e.,  ) are necessary for the assessment of HAN hydrolysis rates at slightly acidic

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pHs. Both of the neutral and basic hydrolysis rate constants for the seven HANs were estimated

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using a Bayesian modeling approach,22 and the details of this statistic estimation method and the

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resulting rate constant estimates will be addressed in the later section.

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In many cases, this hydrolysis model is further stratified into a hierarchical structure22 by parsing it into a 1st-order observed rate constant Kobs, as shown in Equation 2:  =  +  ∙    (. 2)

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Given that HAN hydrolysis has been previously investigated by several teams of

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researchers,7,9,14-17 it is important to reconcile our results with those that have been reported.

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Generally, when pH was below or equal to 8, the 1st-order observed rate constants (i.e., Kobs)

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determined in this work were in agreement with literature values (Figure S2). Certain

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disagreements were noted at higher pHs and the possible explanations for those inter-laboratory

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differences are addressed in the Supporting Information.

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Reaction of Haloacetonitriles in the Presence of Free Chlorine

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The HAN reaction kinetics were further investigated across three pH levels (i.e., pH 5, 6, and

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7) in the presence of free chlorine (initial chlorine dose: 0.5 mg Cl2/L ~ 4.0 mg Cl2/L). It is

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evident in Figure 3 that the presence of free chlorine caused rapid loss of HANs, particularly of

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the THANs (i.e., TCAN and BDCAN), and the rate of loss accelerated with both increasing pH

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and increasing chlorine dose. This chlorine-assisted reaction followed many of the trends noted

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for HAN hydrolysis, with THANs having the highest rate of loss followed by DHANs and finally

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MHANs under all investigated conditions. Furthermore, within each of the three groups, the

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greater the extent of bromination, the longer the HAN persisted. As a result, the stability

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hierarchy for the seven HANs remained the same both with and without the presence of chlorine

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residual. Perhaps more importantly, such a similarity between HAN hydrolysis and chlorination

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behavior implies that the underlying reaction mechanisms might be analogous for these two

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pathways, which will be further explored using liner free energy relationships (LFERs) below.

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Figure 3. Semi-logarithmic plots of residual HAN concentrations versus reaction time under three

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chlorination pH conditions (i.e., pH 5, 6, and 7) with four different initial free chlorine doses (i.e.,

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0.5 mg Cl2/L, 1.0 mg Cl2/L, 2.0 mg Cl2/L, and 4.0 mg Cl2/L). The lines indicate the predicted

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concentrations based on the HAN kinetic model.

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Despite the fact that theoretical HAN chlorination pathways have already been proposed,16,17

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the actual reaction intermediates and end products have not to be verified with quantitative

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laboratory evidence. For this reason, the two exclusively hypothesized intermediates, HAM and

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HAA, were for the first time, quantified during the course of HAN chlorination at a moderate

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chlorination pH (i.e., pH 6) in this study. Results are shown in Figure 4 for DCAN and TCAN as

239

two representative compounds of the entire group.

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Formation of both of the two dichloro- and trichloro-intermediates was observed,

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compensating the loss of DCAN and TCAN under all chlorination conditions. Mainly due to

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more substantial HAN loss that was resulted, the higher was the initial chlorine dose, the more

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was the intermediate formation, especially for DCAA and TCAA. On the other hand, the 13 ACS Paragon Plus Environment

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concentration of HAMs exhibited a slight decrease at longer reaction times (particularly, TCAM

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concentration at pH 6 with 4.0 mg Cl2/L initial chlorine dose), which can be ascribed to their own

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decomposition through reactions with residual chlorine (Yu & Reckhow, unpublished work).

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More importantly, there was a substantial discrepancy between the molar sum of the three HAN,

248

HAM and HAA species and the initial HAN doses (Figure 4). Such a negative deviation from the

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mass balance is indicative of the formation of some other intermediates that were not quantified

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in this study. In a companion study (Yu & Reckhow, unpublished work), we recognized that the

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intermediate HAMs can be further N-chlorinated by HOCl/OCl-, forming the N-chloro-HAMs,

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which will tend to deprotonate and stabilize within the pH range typical of drinking water

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distribution systems (pKa,N-Cl-DCAM=3.71 and pKa,N-Cl-TCAM=2.91).23 Considering the scope of this

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kinetic study, a full description of the byproduct analysis including the relevant chromatographic

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and mass spectroscopic evidence for the identification and quantification of this group of

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halogenated nitrogenous compounds will be presented in a companion paper (Yu & Reckhow,

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2016; manuscript in preparation). However, it is hypothesized that the deprotonated N-chloro-

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HAMs other than the HAMs and HAAs may form as the major reaction intermediates during

259

HAN chlorination due to their relatively high stability.

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Figure 4. Formation of DCAM and DCAA (top row), TCAM and TCAA (bottom row) during

262

DCAN and TCAN chlorination at pH 6. Purple diamonds represent the intermediates that were

263

not identified and quantified in this investigation. The dashed lines indicate the initial DCAN and

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TCAN molar concentrations spiked at the beginning of individual chlorination experiments. Analogous to HAN hydrolysis, the 2nd-order chlorination kinetics can be proposed as follows

265 266

by assuming significant HAN reaction rates with both hypochlorous acid and hypochlorite:

 = −  −     −  !" −  !"   (. 3) 

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To account for the pH-dependent HOCl/OCl- speciation, Equation 3 is reformulated using

268

total free chlorine concentration (i.e., Ct) and dissociation constant Ka24 for hypochlorous acid

269

with corrections for ionic strength (i.e., I):  = −( +     +  $% !& +  $' !& ) ∙  (. 4)  $% =

 )  *,, ; $' = ) (. 5) )   + *,,   + *,, 15 ACS Paragon Plus Environment

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In some of the chlorination experiments, significant depletion of chlorine occurred,

271

particularly when the initial chlorine doses were low. As a result, its concentration cannot be

272

treated as constant without introducing substantial error for the estimation of the chlorination

273

reaction rate constants. For this reason, we numerically integrated residual chlorine over time

274

(i.e., /% !&  ), which is defined as chlorine contact time (CT) and the final kinetic model can be

275

formulated as Equation 6. The estimation of the individual reaction rate constants using the

276

Bayesian estimation framework will be addressed below.

&

&

ln = ln% − ( +    ) ∙ − ($%  + $'  ) ∙ 2 !&  (. 6) %

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Stability of Haloacetonitriles in the Presence of Chloramines

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Because of the continuous reaction with chlorine as demonstrated in the above section, HANs

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are often detected at lower levels in systems that only use free chlorine,20 nevertheless, the total

280

amount of HANs that initially form in those chlorination systems may be substantially greater.17,21

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However, chloramines have not been assessed for their reactivity with HANs to clarify whether

282

the relatively higher occurrence of HANs in most chloramination systems20 is attributed to their

283

greater stability in the presence of chloramines or to the tendency of chloramines to form more

284

HANs as an additional nitrogen source. Therefore, a set of experiments was conducted for the

285

evaluation of HAN stability at a typical chloramination pH (i.e., pH 8.5) with varying doses of

286

preformed chloramines. The use of preformed chloramines instead of forming chloramines in-situ

287

via ammonia addition was done to prevent HANs from reacting with transient free chlorine

288

before the latter had a chance to fully combine with ammonia. Results indicated that there was no

289

significant difference in HAN stability with or without the presence of chloramines at doses up to

290

4 mg/L (as Cl2) (Figure S3), implying that no reactions between HANs and chloramines were

291

significant enough to be detectable under the investigated conditions.

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Estimation of Reaction Rate Constants Using Bayesian Framework

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In this study, the four reaction rate constants (i.e., kH2O, kOH, kHOCl, and kOCl in Equation 6)

294

were estimated in a Bayesian framework, which is an alternative statistic method to the classic

295

least squares regression for the estimation of model parameters. The main benefits of Bayesian

296

estimation are the ability to relax distributional assumptions on parameters, entertain nonlinear

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model structure and most importantly, pool information between experiments in order to reduce

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the influence of outliers and thus providing more robust estimations.22 Moreover, the Bayesian

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framework also allows the inclusion of prior information or expert knowledge when available to

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reduce the uncertainty in model estimation.25,26

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The final distribution of all model parameters, known as the joint posterior distribution

302

(Figure S4) shows that the basic hydrolysis rate constant (i.e., kOH) and the hypochlorite

303

chlorination rate constant (i.e., kOCl) for individual HANs were in the same order of magnitude.

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Moreover, both of the two reaction rate constants ranked in reverse order to the HAN stability

305

hierarchy, increasing with increasing number of halogens, in particular, with the number of

306

chlorine atoms (Table S3). On the contrary, the neutral hydrolysis rate constants (i.e., kH2O) and

307

the hypochlorous acid chlorination rate constants (i.e., kHOCl) were not only estimated to be

308

several orders of magnitude smaller, but also had some fluctuation in terms of following the

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halogenation pattern. Perhaps most importantly, for all the seven HANs, the kHOCl estimates were

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normally distributed around zero, suggesting that given the size of the dataset collected in this

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study, this reaction rate constant proposed in Equation 6 is not estimated to be statistically

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different from zero. As a consequence, the HAN kinetic model can be reduced to Equation 7 by

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dropping the HOCl chlorination term, which will in turn leave the data with higher degrees of

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freedom to allow for more precise estimation of the remaining three reaction rate constants. The

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resulting joint posterior distribution of kH2O, kOH and kOCl (Figure S5 and Table S4) shows that all

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of the three reaction rate constants for MBAN were not statistically different from zero due to its 17 ACS Paragon Plus Environment

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remarkably high stability regardless of pH and chlorine doses. For the other MHAN (i.e., MCAN),

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only kOH is statistically significant and therefore can be estimated with sufficient precision.

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Furthermore, the neutral hydrolysis rate constants (i.e., kH2O) for the two THANs (i.e., BDCAN

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and TCAN) were also noted to be trivial compared to kOH and kOCl. Following the previous

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methodology, all the reaction rate constants were re-estimated by dropping the insignificant terms

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to leave the dataset with more freedom. The final posterior estimates of kH2O, kOH, and kHOCl for

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the seven HANs are listed in Table 1 with 95% confidence intervals. &

ln = ln% − ( +    ) ∙ − $'  ∙ 2 !&  (. 7) %

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Table 1. Estimates of neutral, basic hydrolysis rate constants (kH2O and kOH), and hypochlorite

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chlorination rate constant (kOCl) through Bayesian estimation. kH2O (hr-1) Median 95% C.I.

kOH (M-1hr-1) Median 95% C.I.

MBAN NS MCAN NS DBAN 1.38E-04 (0.46, 2.31) E-04 BCAN 1.36E-04 (0.42, 2.35) E-04 DCAN 1.68E-04 (0.66, 2.70) E-04 BDCAN NS TCAN NS 326 *NS – not significant 327

4.14E+01 1.09E+03 2.57E+03 5.60E+03 4.45E+04 1.23E+05

NS (0.89, 7.35) E+01 (1.03, 1.16) E+03 (2.43, 2.72) E+03 (5.29, 5.91) E+03 (4.20, 4.71) E+04 (1.17, 1.31) E+05

kOCl (M-1hr-1) Median 95% C.I.

1.54E+02 3.24E+02 6.85E+02 1.36E+04 3.91E+04

NS NS (1.23, 1.86) E+02 (2.91, 3.58) E+02 (6.40, 7.30) E+02 (1.30, 1.42) E+04 (3.77, 4.06) E+04

Taft Linear Free Energy Relationships (LFERs)

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The structural impact of reactant on the thermodynamic and kinetic properties of the

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participating reaction is usually assessed using LFERs. Establishing LFERs also helps in the

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understanding of reaction mechanisms and allows the prediction of reaction rates on the

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assumption that compounds with structural similarities behave alike.27-30 The Taft equation

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(Equation 8) was selected for this dataset because it has been previously used in the evaluation of

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the substituent inductive and steric effect on the reactivity of aliphatic acetonitriles.15,31,32 In the 18 ACS Paragon Plus Environment

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Taft equation, K0 is the reaction rate constant for unsubstituted acetonitrile, k is the pathway-

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specific reaction rate constant for a particular HAN with substituent R. σ* and Es are Taft’s polar

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and steric substituent constants (the detailed calculations of these two constants are listed in the

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Supporting Information). The polar and steric sensitivity factors, ρ and δ, are resulting model

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parameters representing the sensitivity of the reaction rate to the substituent polar and steric

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properties across the entire group of HANs. Figure 5 shows the ρ and δ estimates based on the

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estimated median rate constants (Table S4) for two major HAN reactions (i.e., basic hydrolysis

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and chlorination by hypochlorite), via standard nonlinear least squares regression. log

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 = 78 ∗ + : (. 8) %

Since the product of ρσ* is always greater than that of δEs, it can be inferred that both

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reactions are more sensitive to the polar than to the steric property of the halogenated substituents.

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For this reason, the higher hydrolysis and chlorination rates for more halogenated HANs can be

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explained by the higher electron-withdrawing effect from the halogen aggregate, which activates

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the nitrile carbon and renders it more electrophilic, even though the steric hindrance of the

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aggregate also increases with increasing number of halogens. Perhaps most importantly, positive

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ρ estimates for both of the two LFERs reveal the same nucleophilic nature of HAN hydrolysis

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and chlorination reactions; that is, HANs react with hydroxide and hypochlorite through

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nucleophilic attacks on the nitrile carbon. This also explains the absence of certain HAN

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chloramination reactions since chloramines are, in most cases, strong electrophiles.

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Figure 5. Taft LFERs based on median kOH and kOCl estimates.

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Implications of HAN Reaction Kinetics with Respect to Drinking Water Treatment and System

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Management

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With the understanding of HAN reaction kinetics, the persistence of this group of compounds

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in drinking water distribution systems can be predicted based on distributed water pH and

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disinfectant residual. When exact chlorine exposure (i.e., CT) during drinking water distribution

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is not readily available, an averaged chlorine residual !