• Bow of a ship with numerous rust stains.

    Ships have to be overhauled regularly, as wind and waves abrade the paint. Together with the flakes, microplastic particles also end up in the sea. Photo: istock/franswillemblok

An underestimated source of marine microplastic pollution

Marine paints can be a major source of microplastics in the North Sea. In a new study, Oldenburg environmental geochemists hypothesize that ships leave a kind of 'skid mark' in the water.

Marine paints can be a major source of microplastics. In a new study, Oldenburg environmental geochemists hypothesize that ships leave a kind of 'skid mark' in the water.

Shipping traffic can be a major source of tiny plastic particles floating in the sea, especially out in the open ocean. In a paper published in the scientific journal Environmental Science & Technology, a team of environmental geochemists based at the University of Oldenburg's Institute of Chemistry and Biology of the Marine Environment and led by Dr Barbara Scholz-Böttcher for the first time provides an overview of microplastics mass distribution in the North Sea.

The scientists found that most of the plastic particles in water samples taken from the German Bight, an area in the south-eastern corner of the North Sea which encompasses some of the world's busiest shipping lanes, originate from binders used in marine paints. "Our hypothesis is that ships leave a kind of 'skid mark' in the water which is of similar significance as a source of microplastics as tyre wear particles from cars are on land," Scholz-Böttcher says.

A comprehensive picture

In the autumn of 2016 and 2017, the Oldenburg team took water samples from various locations in the German Bight with the research vessel "Heincke". Scholz-Böttcher and her two colleagues Christopher Dibke and Marten Fischer used stainless steel sieves to filter plastic particles of much less than one millimetre in diameter out of the seawater and then analysed the chemical composition of the collected particles. They used a special analytical method in which the plastic molecules were first heated to temperatures of almost 600 degrees Celsius to break them down into smaller, characteristic fragments, and then separated and assigned to different polymer groups based on their mass and chemical properties. With this method the researchers were also able to quantify the mass of each plastic type. "Previous studies have only measured particle numbers for the North Sea. We, for the first time, also determined the mass distribution, and thus obtained a more comprehensive picture of the emergence of the different plastic types," Scholz-Böttcher stresses.

The team was surprised by the results: the samples contained above all indicators for polyvinyl chloride (PVC), polymers known as acrylates, and polycarbonates. Their mass accounted for about two-thirds of the total microplastic content in the mean and up to 80 percent in certain samples. Packaging plastics such as polyethylene (PE), polypropylene (PP) and polyethylene terephthalate (PET), which were previously estimated to make up the bulk of microplastics in the sea, accounted for a much smaller percentage. "We weren't expecting this distribution pattern," says Scholz-Böttcher.   

Microplastics produced directly at sea

When the researchers conducted a more detailed analysis of the results they observed that PE, PP and PET plastics were found mainly near the coastline, whereas in the open North Sea and in the Elbe estuary – particularly in the proximity of major shipping routes – the other types of plastic were predominant. "We believe that these particles originate from ship coatings, where these plastics are used as binders in acrylic paints or epoxy resins, for example," Scholz-Böttcher explains. These results suggest that far larger quantities of microplastics are produced directly at sea than previously thought.

According to the team, literature studies show that in the European Union alone, several thousand tonnes of paint end up in the marine environment every year. With potentially harmful consequences for the environment: coatings and paints used on ships contain heavy metals and other additives that are toxic to many organisms. These antifouling components are used to protect ships' hulls from barnacles and other subaquatic organisms and are constantly rubbed off by the wind and waves. The team is currently conducting further studies, for example in river estuaries and in sediments, to gain more insights into how these microplastics enter the environment.

 

This might also be of interest to you:

Microscopic picture of a microbial community.
Excellence Strategy Research Top News Marine Sciences

"Completely new worlds"

Computer scientist A. Murat Eren, who goes by Meren, is convinced that microbiology can contribute to solving many global challenges. In this…

more
The picture shows a coral landscape in the Red Sea. The corals are reddish-brown in colour and are only a few meters below the surface.
Excellence Strategy Research Top News Marine Sciences

New concept for the protection of marine biodiversity

Climate change also affects the oceans. But how can the marine life affected by it be protected beyond the scope of national jurisdiction? A new…

more
Image of a boulder in the Atlantic at a depth of 560 metres. On the rocks are brittle stars and crinoids, important organisms in the deep-sea ecosystem.
Excellence Strategy Research Top News Marine Sciences

"One feels like a true explorer"

The oceans are home to much of the planet's biodiversity. They have a major influence on our climate and provide food for billions of people. To mark…

more
Presse & Kommunikation (Changed: 18 Oct 2024)  | 
Zum Seitananfang scrollen Scroll to the top of the page