Banned Chemicals Found in the Ocean
Credit: Dr Alan Jamieson, Newcastle University
A study, led by Newcastle University’s Dr Alan Jamieson has uncovered the first evidence that man-made pollutants have now reached the farthest corners of our earth. Sampling amphipods from the Pacific Ocean’s Mariana and Kermadec trenches - which are over 10 kilometres deep and 7,000 km apart - the team found extremely high levels of Persistent Organic Pollutants (POPs) in the organism’s fatty tissue. These include polychlorinated biphenyls (PCBs) and polybrominated diphenyl ethers (PBDEs) which are commonly used as electrical insulators and flame retardants.
Publishing their findings today in Nature Ecology & Evolution, the team from Newcastle University, University of Aberdeen and the James Hutton Institute, say the next step is to understand the consequences of this contamination and what the knock-on effects might be for the wider ecosystem.
“We still think of the deep ocean as being this remote and pristine realm, safe from human impact, but our research shows that, sadly, this could not be further from the truth. In fact, the amphipods we sampled contained levels of contamination similar to that found in Suruga Bay, one of the most polluted industrial zones of the northwest Pacific. What we don’t yet know is what this means for the wider ecosystem and understanding that will be the next major challenge.”
From the 1930s to when PCBs were banned in the 1970s, the total global production of these chemicals was in the region of 1.3million tonnes. Released into the environment through industrial accidents and discharges and leakage from landfills, these pollutants are invulnerable to natural degradation and so persist in the environment for decades.
The research team used deep-sea landers, designed by Dr Jamieson, to plumb the depths of the Pacific Ocean in order to bring up samples of the organisms that live in the deepest levels of the trenches. The authors suggest that the pollutants most likely found their way to the trenches through contaminated plastic debris and dead animals sinking to the bottom of the ocean, where they are then consumed by amphipods and other fauna, which in turn become food for larger fauna still.
“The fact that we found such extraordinary levels of these pollutants in one of the most remote and inaccessible habitats on earth really brings home the long term, devastating impact that mankind is having on the planet,” says Dr Jamieson, who is based in the School of Marine Science and Technology at Newcastle University. “It’s not a great legacy that we’re leaving behind.”
Oceans comprise the largest biome on the planet, with the deep ocean operating as a potential sink for pollutants and litter that are discarded into the seas. These pollutants then accumulate through the food chain so that by the time they reach the deep ocean, concentrations are many times higher than in surface waters.
“This research shows that far from being remote the deep ocean is highly connected to the surface waters. We’re very good at taking an ‘out of sight out of mind’ approach when it comes to the deep ocean but we can’t afford to be complacent."
Jamieson, A. J., Malkocs, T., Piertney, S. B., Fujii, T., & Zhang, Z. (2017). Bioaccumulation of persistent organic pollutants in the deepest ocean fauna. Nature Ecology & Evolution, 1, 0051. doi:10.1038/s41559-016-0051
This article has been republished from materials provided by Newcastle University. Note: material may have been edited for length and content. For further information, please contact the cited source.
Foods From Uncoated Aluminium Menu Trays Contain High Aluminium LevelsNews
A BfR research project, which examined several foods prepared in line with the rules of the Cook&Chill process before being kept warm, found high levels of aluminium.READ MORE
Boehringer Selects NOVA-EM for Their Global Environmental Monitoring ProgramNews
Boehringer Ingelheim plans to implement and validate the NOVA-EM (Environmental Monitoring) solution at multiple sites worldwide.
Copper Catalyst Converts Carbon Dioxide to EthanolNews
Stanford discovery could lead to sustainable source of the fuel additive ethanolREAD MORE