Applying the polarity rapid assessment method to characterize nitrosamine precursors and to understand their removal by drinking water treatment processes

Some N-nitrosamines (NAs) have been identified as emerging disinfection by-products during water treatment. Thus, it is essential to understand the characteristics of the NA precursors. In this study, the polarity rapid assessment method (PRAM) and the classical resin fractionation method were studi...

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Bibliographic Details
Published in:Water research (Oxford) 2015-12, Vol.87, p.292-298
Main Authors: Liao, Xiaobin, Bei, Er, Li, Shixiang, Ouyang, Yueying, Wang, Jun, Chen, Chao, Zhang, Xiaojian, Krasner, Stuart W., Suffet, I.H. (Mel)
Format: Article
Language:English
Subjects:
Assessments
Byproducts
Cartridges
Cationic
Chemical Fractionation
Disinfection by-product
Drinking water
Drinking Water - analysis
Drinking Water - chemistry
Drinking water treatment process
Nitrosamine
Nitrosamines - analysis
Nitrosamines - chemistry
Polarity rapid assessment method
Polymers
Precursor
Precursors
Resin fractionation
Resins
Water Purification - methods
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Summary:Some N-nitrosamines (NAs) have been identified as emerging disinfection by-products during water treatment. Thus, it is essential to understand the characteristics of the NA precursors. In this study, the polarity rapid assessment method (PRAM) and the classical resin fractionation method were studied as methods to fractionate the NA precursors during drinking water treatment. The results showed that PRAM has much higher selectivity for NA precursors than the resin approach. The normalized N-nitrosodimethylamine formation potential (NDMA FP) and N-nitrosodiethylamine (NDEA) FP of four resin fractions was at the same level as the average yield of the bulk organic matter whereas that of the cationic fraction by PRAM showed 50 times the average. Thus, the cationic fraction was shown to be the most important NDMA precursor contributor. The PRAM method also helped understand which portions of the NA precursor were removed by different water treatment processes. Activated carbon (AC) adsorption removed over 90% of the non-polar PRAM fraction (that sorbs onto the C18 solid phase extraction [SPE] cartridge) of NDMA and NDEA precursors. Bio-treatment removed 80–90% of the cationic fraction of PRAM (that is retained on the cation exchange SPE cartridge) and 40–60% of the non-cationic fractions. Ozonation removed 50–60% of the non-polar PRAM fraction of NA precursors and transformed part of them into the polar fraction. Coagulation and sedimentation had very limited removal of various PRAM fractions of NA precursors. [Display omitted] •First to apply the Polarity Rapid Assessment Method (PRAM) to characterize nitrosamine precursors in a drinking water source.•The cationic fraction of PRAM had 50 times the average level of the normalized nitrosamine formation potential (FP).•Also, first to apply PRAM to study nitrosamine precursor removal by various treatment processes.•Activated carbon adsorption preferentially removed the non-polar nitrosamine precursors.•Bio-treatment preferentially removed the cationic fraction of the nitrosamine precursors.
ISSN:0043-1354
1879-2448
DOI:10.1016/j.watres.2015.09.040