We’ve all seen the documentaries that feature scenes of mass migrations on land. Those videos are pretty impressive showing all sorts of animals — birds, mammals and other creatures — on the move. What wasn’t known was to what extent this was taking place in the deepest parts of our oceans.
That was until now.
Scientists have, for the first time, documented seasonal migrations of fish across the seafloor in deep-sea fish, revealing an important insight that will further scientific understanding of the nature of our planet.
“We are extremely excited about our findings, which demonstrate a previously unobserved level of dynamism in fishes living on the deep sea floor, potentially mirroring the great migrations which are so well characterised in animal systems on land,” said Rosanna Milligan, Assistant Professor at Nova Southeastern University, who started the work at the University of Glasgow.
The study — published today in the Journal of Animal Ecology and led by Nova Southeastern University (NSU) and the University of Glasgow — analysed more than seven years of deep-sea photographic data from West Africa, linking seasonal patterns in surface-ocean productivity with observed behavioural patterns of fishes at 1,500 metres.
The deep sea — greater than 200-meters water depth — covers most of the world’s surface. Recent advances in technology and computational power have hugely improved our ability to access and study deep sea ecosystems, but there are still many basic questions that we simply don’t have answers to.
This study now provides evidence of cycles of movement across the seafloor in deep-sea fish, with the study authors believing these movements could be happening in other locations across the world’s sea floor too.
This work was only possible because of an international collaboration between industry, academia and government, involving more than 10 organisations across Angola, UK and US. It was done using the Deep-ocean Environmental Long-term Observatory System (DELOS).
The DELOS observatories are permanently left in place on the seafloor (1,400 m depth) and house separate instrumentation “modules” containing oceanographic sensors, cameras and more. The modules are periodically recovered for data download and servicing using a remotely-operated vehicle (ROV).
You can learn more about the DELOS project ONLINE.
“The work really adds to our understanding of movement patterns in deep-sea fishes and suggests reasons for their behaviours, Milligan said. “Because we were able to link the abundances of fish observed at the seafloor to satellite-derived estimates of primary productivity, our results suggest that even top-level predators and scavengers in the deep oceans could be affected by changes filtering down from the surface of the ocean.”
Dr. David Bailey, Senior Lecturer in Marine Biology at the University of Glasgow’s Institute of Biodiversity, Animal Health and Comparative Medicine, said: “Animal migrations are really important in nature, because when animals move from place to place, they transport energy, carbon and nutrients. We were only able to discover this behaviour because of the collective expertise and decade-long commitment of the Universities and industry partners. These kinds of long-term projects and the datasets they generate are vital to understanding ongoing change in the oceans and how they may be impacted in the future.”