A new study shows that the impacts of seabed mining on deep-sea ecosystems can persist for decades.
Scientists at the U.K.'s National Oceanography Centre (NOC) revisited a site exposed to deep-sea mining activity nearly 30 years previously to assess seabed and ecosystem recovery. They used a robot submarine to map and photograph much of the seafloor in the disturbed area in unprecedented detail. The images were combined into a seafloor photo-mosaic completely covering 11 hectares of seabed, the largest ever photo-mosaic obtained in the abyssal ocean. Tracks on the seafloor caused by the simulated mining were still clearly visible, and the impacts on marine life initially observed in 1989 persist.
The study, recently published in Scientific Reports, was able to pinpoint individual animals over a wide area and relate their abundance and distribution to the tracks. While mobile species, such as sea cucumbers and sea stars, were able to recolonize impacted areas, many animals, such as sponges and sea anemones, live attached to the seafloor and remained virtually absent from directly disturbed seabed. Given the important role of these animals in abyssal ecosystems, the results of the study suggest that impacts of large-scale commercial mining could potentially lead to an irreversible loss of key ecosystem functions, says the NOC.
The target of this type of deep-sea mining is polymetallic nodules, potato-shaped rocks rich in copper and manganese. These nodules provide a stable anchoring point for the development of anemones, soft corals and sponges, and promote the development of diverse communities on otherwise muddy seabed. The nodules take millions of years to form. Removal or burial of nodules from mining activities will remove the home of many of these filter-feeding animals, constraining their capacity to recolonize impacted zones and further delaying ecosystem recovery processes.