Mechanism of chlorination of threonine disinfection by-product trichloroacetone in drinking water

doi:10.11949/j.issn.0438-1157.20151906

Abstract

Abstract:

In order to inspect the process of L-threonine chloride to TCAce and its influencing factors, a novel method using methyl tertiary butyl ether (MTBE) as extractant and 1,2-dibromopropane as internal standard for the determination of the disinfection by-products trichloroacetone (TCAce) by gas chromatography mass spectrometry(GC-MS) was described．The formation process of TCAce and its influencing factors were discussed with L- threonine as the precursor during the chloramination process．It was indicated from the formation process that the TCAce amount produced increased with the increase of pH value from 5.5 to 8.5. Under the experimental conditions, it was also shown that when the chlorine dosage increased from 5.46 to 21.84 ml, the TCAce formation amount increased. It was also shown that when the L-threonine dosage increased from 59.6 to 476.4 mg·L^-1, the TCAce formation amount decreased. Temperature affected the TCAce formation from L-threonine a lot, especially in the range of 10—30℃. The TCAce formation amount increased with the increase of temperature. The formation process of TCAce chlorided by L-threonine contained substitution, oxidation reaction, amino diazotation, reduction and a series of complicated reaction.

Key words: chromatography, solvent extraction, TCAce, precursor, process control, formation mechanism

摘要：

为了考察饮用水中消毒副产物三氯丙酮（TCAce）的形成过程和影响因素，采用气相色谱-质谱法，以甲基叔丁基醚为萃取剂，1,2-二溴丙烷为内标物，建立了消毒副产物三氯丙酮（TCAce）的测定方法。以L-苏氨酸为前体，考察在不同反应条件下三氯丙酮的生成效果，并探讨了TCAce的形成途径。结果表明：TCAce的生成量在碱性条件下高于中性和酸性条件，在5.5~8.5的pH范围内，随着pH的增大而逐渐提高。在试验条件下，当氯投加量由5.46 ml增加到21.84 ml时，TCAce的生成量随投氯量的增加而增加。当前体物L-苏氨酸投加量由59.6 mg·L^-1增加到476.4 mg·L^-1时，TCAce的生成量随投加量的增大而减小，当反应温度由10℃增加到30℃时，TCAce的生成量随之增加。HClO氯化L-苏氨酸形成TCAce的过程包含7个步骤，包括取代、氧化、氨基重氮化和还原等复杂的过程。

关键词: 色谱, 溶剂萃取, 三氯丙酮, 前体, 过程控制, 形成机制

CLC Number:

DING Chunsheng, ZHANG Mengqing, ZOU Bangwen, LI Naijun. Mechanism of chlorination of threonine disinfection by-product trichloroacetone in drinking water[J]. CIESC Journal, 2016, 67(7): 3010-3015.

丁春生, 章梦青, 邹邦文, 李乃军. 苏氨酸氯化生成饮用水中消毒副产物三氯丙酮的机制[J]. 化工学报, 2016, 67(7): 3010-3015.

References 24

[1]	RICHARDSON S D, PLEWA M J, WAGNER E D, et al. Occurrence, genotoxicity, and carcinogenicity of regulated and emerging disinfection by-products in drinking water: a review and roadmap for research[J]. Mutat. Res.-Rev. Mutat. Res., 2007, 636(1/2/3): 178-242.
[2]	丁春生, 沈嘉辰, 缪佳, 等. 改性活性炭吸附饮用水中三氯硝基甲烷的研究[J]. 中国环境科学, 2013, 33(5): 821-826. DING C S, SHEN J C, MIAO J, et al. Adsorption of trichloronitromethane in drinking water by modified activated carbon[J]. China Environmental Science, 2013, 33(5): 821-826.
[3]	孟丽苹, 董兆敏, 胡建英. 全国自来水厂卤乙酸浓度调查、风险评估与标准建议[J]. 中国环境科学, 2012, 32(4): 721-726. MENG L P, DONG Z M, HU J Y. National survey and risk assessment of haloacetic acids in drinking water in China for reevaluation of the drinking water standards[J]. China Environmental Science, 2012, 32(4): 721-726.
[4]	葛元新, 朱志良, 陆雍森, 等. 饮用水消毒的健康风险分析及评价[J]. 净水技术, 2006, 25(3): 1-5. GE Y X, ZHU Z L, LU Y S, et al. Analysis and assessment of health risk on disinfection of drinking water[J]. Water Purification Technology, 2006, 25(3): 1-5.
[5]	MARK J N, MIREILLE B T, NAOMI E E. Chlorination disinfection by products in water and their association with adverse reproductive: a review [J]. Occupational and Environmental Medicine, 2000, 57: 73-85.
[6]	ARDIFF R G, CARSON M L, GINERAN M E. Updated weight of evidence for an association between adverse reproductive and developmental effects and exposure and exposure to effects and exposure to disinfection by products [J]. Regul. Toxicol. Pharmacol., 2006, 45: 185-205.
[7]	KOIVUSALO M, PUKKALA E, VARTIAINEN T, et al. Drinking water chlorination and cancer historicalcohort study in Finland [J]. Cancer Causes Control, 1997, 8(2): 192-200.
[8]	高乃云, 楚文海. 饮用水中氯代丙酮类消毒副产物的分析方法研究[J]. 水工业市场, 2011, 7: 39-42. GAO N Y, CHU W H. Analysis method in chlorinated drinking water disinfection by-products of acetone category[J].Water Industry Market, 2011, 7: 39-42.
[9]	FRANK L C, DANIEL M, FRANCOISE E. Study of the genotoxic activity of five chlorinated propanones using the SOS chromotest, the ames-fluctuation test and the newt micronucleus test[J]. Mutation Research /Genetic Toxicology and Environmental Mutagenesis, 1994, 341(1): 1-15.
[10]	SINGER P C. Humic substances as precursors for potentially harmful disinfection by products[J]. Water Science and Technology, 1999, 40(9): 25-30.
[11]	CHU W H, GAO N Y, DENG Y, et al. Precursors of dichloroacetamide, an emerging nitrogenous DBP formed during chlorination or chloramination[J]. Environ. Sci. Technol., 2010, 44(10): 3908-3912.
[12]	CHU W H, GAO N Y, DENG Y, et al. Peptide bonds affect the formation of haloacetamides, an emerging class of N-DBPs in drin-king water: free amino acids versus oligopeptides[J]. Sci. Rep., 2015, 5: 14412.
[13]	WESTERHOFF P, MASH H. Dissolved organic nitrogen in drinking water supplies: a review[J].Water Supply Res.Technol.-Aqua, 2002, 51: 415-448.
[14]	王超, 胡洪营, 王丽莎, 等. 典型含氮有机物的氯消毒副产物生成潜能研究[J]. 中国给水排水, 2006, 22(15): 9-12. WANG C, HU H Y, WANG L S, et al. Chlorination byproducts formation potentials of typical nitrogenous organic compounds[J]. China Water &Wastewater, 2006, 22(15): 9-12.
[15]	王海鸥, 陈忠林. 氯胺和联合氯胺控制消毒副产物的研究[J]. 黑龙江大学自然科学学报, 2010, 27(6): 764-773. WANG H O, CHEN Z L. Study on control of disinfection by-products with chloramines and combined chloramines[J]. Journal of Natural Science of Heilongjiang University, 2010, 27(6): 764-773.
[16]	EGOROV A I, TERESCHENKO A A, ALTSHUL L M, et al. Exposures to drinking water chlorination by-products in a Russian city[J]. International Journal of Hygiene and Environmental Health, 2003, 206(6): 539-551.
[17]	DOSTSON A, WESTERHOF P. Occurrence and removal of amino acids during drinking water treatment[J]. J. Am. Water Work Assoc., 2009, 101: 101-115.
[18]	Determination of haloacetic acids and dalapon in drinking water by liquid-liquid extraction, derivatization and gas chromatography with electron capture detection: US EPA Method552. 2 [S]. 1998.
[19]	丁春生. 饮用水中三氯硝基甲烷的形成过程与控制技术研究 [D]. 昆明: 昆明理工大学, 2012. DING C S. Research on formation process of trichloromethane, disinfection by-product in drinking water and its control strategies [D]. Kunming: Kunming University of Science and Technology, 2012.
[20]	黄剑明, 需廷国, 胡静, 等. 饮用水氯胺消毒技术应用现状及面临的课题[C]//城镇饮用水安全保障技术研讨会论文集. 深圳, 2004: 418-422. HUANG J M, XU T G, HU J, et al. Chloramine disinfection of drinking water application status and challenges facing[C]//Urban Drinking Water Safety Technical Symposium. Shenzhen, 2004: 418-422.
[21]	CHEN Z, YANG C Y, LU J, et al. Factors on the formation of disinfection by-products MX, DCA and TCA by chlorination of fulvic acid fromlake sediments[J]. Chemosphere, 2001, 45: 379-385.
[22]	NIKOLAOU A D, LEKKAS T D, GOLFINOPOULOS S K. Kinetics of the formation and decomposition of chlorination by-products in surface waters[J]. Chemical Engineering Journal, 2004, 100: 139-148.
[23]	RECKHOW D A, SINGER P C. Mechanisms of organic halide formation during fulvic acid chlorination and implications with respect to preozonation[M]//JOLLEY R L, BULL R J, DAVIS W P, et al. Water Chlorination: Chemistry, Environmental Impact and Health Effects. Chelsea, MI: Lewis Publishers, 1985: 1229-1257.
[24]	徐倩, 徐斌, 覃操, 等. 水中典型含氮有机物氯化生成消毒副产物的潜能研究[J]. 环境科学, 2011, 32(7): 1967-1973. XU Q, XU B, QIN C, et al. Chlorination byproducts formation potentials of typical nitrogenous organic compounds in water[J]. Journal of Environmental Sciences, 2011, 32(7): 1967-1973.