Deep-Sea Mining Could Destroy Marine Ecosystems, Study Says

Credit: GCE NODE


“The deep sea covers about half of the Earth’s surface and is home to a vast range of species,” said University of Exeter marine biologist Dr. David Santillo and co-authors.

“Little is known about these environments, and mining could have long-lasting and unforeseen consequences — not just at mining sites but also across much larger areas.”

The study is the first to give a global overview of all current plans to mine the seabed, in both national and international waters, and looks at the potential impacts including physical destruction of seabed habitats, creation of large underwater plumes of sediment and the effects of chemical, noise and light pollution arising from mining operations.

“Our knowledge of these ecosystems is still limited, but we know they’re very sensitive,” Dr. Santillo said.

“Recovery from man-made disturbance could take decades, centuries or even millennia, if these ecosystems recover at all.”

“As we learn more about deep sea ecosystems and the role of oceans in mitigating climate change, it seems wise to take precautions to avoid damage that could have long-lasting and unforeseen consequences.”

Despite the term ‘mining,’ much seabed mining would involve extraction of minerals over very wide areas of the sea floor rather than digging down to any great depth, potentially leaving a vast ‘footprint’ on the deep-sea habitats in which these mineral deposits occur.

Rising demand for minerals and metals, including for use in new technology, has sparked renewed interest in seabed mining. Some operations are already taking place, generally at relatively shallow depths near national coastlines.

The first commercial enterprise, expected to target mineral-rich sulfides in deeper waters, at depths between 1,500 and 2,000 m on the continental shelf of Papua New Guinea, is scheduled to begin early in 2019.

“There are many questions and uncertainties around seabed mining, including legal issues and the difficulties of predicting the scale and extent of impacts in advance, and of monitoring and regulating mining activity once it takes place in the deep sea,” the researchers said.

A schematic showing the processes involved in deep-sea mining for the three main types of mineral deposit. Image credit: Design Studio, University of Exeter.

“Alternatives to seabed mining have already been proposed, including substituting metals in short supply for more abundant minerals with similar properties, as well as more effective collection and recycling of components from disused products and wastes.”

“However, demand for seabed mining would also diminish if humanity could cut overproduction and overconsumption of consumer goods,” Dr. Santillo added.

“Rather than using human ingenuity to invent more and more consumer products that we don’t actually need, we could deploy it instead to build goods that last longer, are easier to repair and make better use of the limited natural resources we have.”

“With the right approaches, we can avoid the need for seabed mining altogether and stop the ‘race to the bottom’.”

“As governments prepare to set the rules and the first companies gear up to mine, now is the time to ask whether we just have to accept seabed mining, or should instead decide that the potential damage is just so great that we really need to find less destructive alternatives.”

Source :

Sci News

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