Difference between revisions of "PCBs and organochlorine pesticides in Antarctic algae"
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'''<u>Content of the study</u>''' | '''<u>Content of the study</u>''' | ||
− | Antarctic | + | Antarctic particulate matter (which includes phytoplankton) and zooplankton were sampled and investigated for the presence of [[organochlorine compounds]] |
<u>'''Main results of the study'''</u> | <u>'''Main results of the study'''</u> | ||
+ | |||
+ | The PCB contamination of oceanic particulate matter is of the same order of magnitude in the Antarctic waters as in the North Sea (600-1200 ng/g dry weight). One would expect Antarctic waters however to be less contaminated than the heavily polluted North Sea. This however is confirmed when the concentration of PCBs is expressed per volume of sea water: then the concentration of PCBs is 7 times higher in the North Sea (8,8 µg/l) than in Antarctica (1,2 µg/l). This leads to the paradoxical consequence that although the Antarctic ecosystem is seven times less contaminated, the Antarctic wild life can be as (or even more) contaminated than in the North Sea. | ||
+ | This confirmed at zooplankton level, which is equally contaminated by food uptake: the Antarctic zooplankton is equally contaminated as the North Sea zooplankton. | ||
+ | The reason for this is that PCBs are insoluble and [[adsorb]] to particles (organic matter). Due to the lower productivity in the Antarctic, less particles are available for the PCBs to adsorb on. Therefore, the lower amount of particles (number/l) compensates for the lower PCB concentration (expressed as µg/l). The zooplankton which feeds on this particulate matter will therefore accumulate the same amount of PCBs. | ||
+ | Pesticides such as DDT were not detectable or only detected at low concentrations.<ref>Joiris, C.R.; Overloop, W. (1991). PCBs and organochlorine pesticides in phytoplankton and zooplankton in the Indian sector of the Southern ocean. Antarctic Science 3: 371-377</ref> | ||
+ | |||
+ | ==References== | ||
+ | <references/> |
Revision as of 16:10, 10 July 2009
Context of the study
Although a wide range of Antarctic organisms, like krill, fish, birds, dolphins and seals have been reported to be contaminated by DDTs and PCBs, no data is available on phytoplankton. Determining the contamination of the Antarctic biota will provide information that can help in controlling global pollution.
Content of the study
Antarctic particulate matter (which includes phytoplankton) and zooplankton were sampled and investigated for the presence of organochlorine compounds
Main results of the study
The PCB contamination of oceanic particulate matter is of the same order of magnitude in the Antarctic waters as in the North Sea (600-1200 ng/g dry weight). One would expect Antarctic waters however to be less contaminated than the heavily polluted North Sea. This however is confirmed when the concentration of PCBs is expressed per volume of sea water: then the concentration of PCBs is 7 times higher in the North Sea (8,8 µg/l) than in Antarctica (1,2 µg/l). This leads to the paradoxical consequence that although the Antarctic ecosystem is seven times less contaminated, the Antarctic wild life can be as (or even more) contaminated than in the North Sea. This confirmed at zooplankton level, which is equally contaminated by food uptake: the Antarctic zooplankton is equally contaminated as the North Sea zooplankton. The reason for this is that PCBs are insoluble and adsorb to particles (organic matter). Due to the lower productivity in the Antarctic, less particles are available for the PCBs to adsorb on. Therefore, the lower amount of particles (number/l) compensates for the lower PCB concentration (expressed as µg/l). The zooplankton which feeds on this particulate matter will therefore accumulate the same amount of PCBs. Pesticides such as DDT were not detectable or only detected at low concentrations.[1]
References
- ↑ Joiris, C.R.; Overloop, W. (1991). PCBs and organochlorine pesticides in phytoplankton and zooplankton in the Indian sector of the Southern ocean. Antarctic Science 3: 371-377