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Vertical transport and residence time of chlorinated hydrocarbons in the open ocean water column

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Abstract

The vertical transport of PCBs and chlorinated hydrocarbon pesticides such as DDT compounds and HCH (BHC) isomers in the deep sea are discussed on basis of their vertical profiles and the proportion of their adsorbed and dissolved fractions in surface water surveyed in the Western Pacific, Eastern Indian and Antarctic Oceans.

All chlorinated hydrocarbons determined were detected with measurable concentrations throughout the water column, even at depths of several thousand meters. The vertical distributions of PCBs and DDT compounds were found to show small variations in concentration throughout the water column, whereas HCH isomer concentrations decreased systematically with depth. A large portion of DDT compounds in surface water was adsorbed on suspended solids, while most of the HCH isomers were present in the filtered water. The proportion of PCBs adsorbed on suspended solids was smaller than the proportion of DDT compounds, but was much greater than that of HCH isomers. These observations suggest that HCH isomers have been slowly scavenged from the surface to the deeper layers in the water column, while PCBs and DDT compounds have been rapidly and abundantly transported downward by sinking particles.

The percentages of chlorinated hydrocarbons adsorbed on suspended solids in surface water increased towards the high latitude locations, and the percentage seemed to be proportional to the concentration of suspended solids in the surface water. This implies that the residence time of chlorinated hydrocarbons in the water column will differ significantly among oceans that differ in primary productivity. According to our estimation based on the data presented in this study, the residence time ofσHCH in the euphotic zone, the top 100 m of the water column, is more than 2 years, whereas those of PCBs andσDDT are less than 1 year. The longest residence time, of from 5 to 10 years, was obtained forσHCH in oligotrophic water of the western North Pacific. The shortest value, only 11 to 19 days, was estimated forσDDT in the Antarctic Ocean.

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  1. Department of Environment Conservation, Ehime University, Tarumi 3-5-7, 790, Matsuyama, Japan

    Shinsuke Tanabe & Ryo Tatsukawa

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  1. Shinsuke Tanabe
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  2. Ryo Tatsukawa
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Tanabe, S., Tatsukawa, R. Vertical transport and residence time of chlorinated hydrocarbons in the open ocean water column. Journal of the Oceanographical Society of Japan 39, 53–62 (1983). https://doi.org/10.1007/BF02210759

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