机构地区:[1]State Key Joint Laboratory of Environmental Simulation and Pollution Control,School of Environment,Tsinghua University, Belting 100084, China [2]School of Chemical Engineering,China University of Petroleum(East China), qingdao 266580, China
出 处:《Journal of Environmental Sciences》2017年第8期331-339,共9页环境科学学报(英文版)
基 金:supported by the National Natural Science Foundation of China (No.21477059);the National Water Major Project (No.2015ZX07402-002);the Fundamental Research Funds for the Central Universities (No.15CX02016A);the Tsinghua University Initiative Scientific Research Program (No.20131089247);the open project of State Key Joint Laboratory of environmental simulation and pollution control (Tsinghua University)
摘 要:N-nitrosodimethylamine(NDMA) precursors consist of a positively charged dimethylamine group and a non-polar moiety, which inspired us to develop a targeted cation exchange technology to remove NDMA precursors. In this study, we tested the removal of two representative NDMA precursors, dimethylamine(DMA) and ranitidine(RNTD), by strong acidic cation exchange resin. The results showed that pH greatly affected the exchange efficiency, with high removal(DMA 〉 78% and RNTD 〉 94%) observed at pH 〈 pk_a-1 when the molar ratio of exchange capacity to precursor was 4. The exchange order was obtained as follows: Ca^(2+)〉 Mg^(2+)〉 RNTD~+〉 K~+〉 DMA~+〉 NH_4~+〉 Na~+. The partition coefficient of DMA~+to Na~+was 1.41 ± 0.26, while that of RNTD~+to Na~+was 12.1 ± 1.9. The pseudo second-order equation fitted the cation exchange kinetics well. Bivalent inorganic cations such as Ca^(2+)were found to have a notable effect on NA precursor removal in softening column test. Besides DMA and RNTD, cation exchange process also worked well for removing other 7 model NDMA precursors. Overall, NDMA precursor removal can be an added benefit of making use of cation exchange water softening processes.N-nitrosodimethylamine(NDMA) precursors consist of a positively charged dimethylamine group and a non-polar moiety, which inspired us to develop a targeted cation exchange technology to remove NDMA precursors. In this study, we tested the removal of two representative NDMA precursors, dimethylamine(DMA) and ranitidine(RNTD), by strong acidic cation exchange resin. The results showed that pH greatly affected the exchange efficiency, with high removal(DMA 〉 78% and RNTD 〉 94%) observed at pH 〈 pk_a-1 when the molar ratio of exchange capacity to precursor was 4. The exchange order was obtained as follows: Ca^(2+)〉 Mg^(2+)〉 RNTD~+〉 K~+〉 DMA~+〉 NH_4~+〉 Na~+. The partition coefficient of DMA~+to Na~+was 1.41 ± 0.26, while that of RNTD~+to Na~+was 12.1 ± 1.9. The pseudo second-order equation fitted the cation exchange kinetics well. Bivalent inorganic cations such as Ca^(2+)were found to have a notable effect on NA precursor removal in softening column test. Besides DMA and RNTD, cation exchange process also worked well for removing other 7 model NDMA precursors. Overall, NDMA precursor removal can be an added benefit of making use of cation exchange water softening processes.
关 键 词:Ion exchange Cation exchange resin N-nitrosamine precursors Dimethylamine Ranitidine
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