
Next year, scientists will deploy a swarm of aerial drones, autonomous submarines and ice sensors in a major coordinated effort to better understand how and why icebergs break off from the Greenland ice sheet.
The , which is backed by 拢16 million of funding from the UK鈥檚 Advanced Research and Invention Agency (ARIA), aims to improve estimates of how much fresh water is entering the North Atlantic from Greenland ice melt.
The answer is crucial for delivering accurate predictions of the rate of sea level rise the world can expect over the coming century. It will also help scientists determine how quickly the Atlantic meridional overturning circulation (AMOC), a vital ocean current that transports nutrients and warm water from the tropics to northern Europe, will weaken in response to climate change.
Advertisement
快猫短视频s are worried a huge influx of cold meltwater from the Arctic could weaken the AMOC to the point of irreversible collapse, perhaps within decades, an outcome that would have devastating effects on the UK and northern Europe. But there remains huge uncertainty over the timing of any potential collapse.
鈥淭he whole idea of GRAIL is really to get how quickly the Greenland ice sheet is melting and how quickly that meltwater, that fresh water, gets into the North Atlantic,鈥 says at the British Antarctic Survey, the organisation leading the GRAIL project.
Iceberg calving is particularly important to understand because calving events can destabilise inland ice, which will then make its way to the ocean, says at the University of Cambridge, who isn鈥檛 involved in the project. 鈥淚f you calve away at the edge of a floating ice tongue, then it will remove a buttressing on the inland ice,鈥 he says. 鈥淚t will allow the inland ice to flow more rapidly.鈥
But accurately assessing the calving of icebergs from Greenland glaciers is notoriously difficult and dangerous. It requires researchers to get instruments up close to towering ice cliffs 鈥 which could break away at any moment 鈥 to measure the temperature, salinity and turbulence of the water butting against the ice. 鈥淭his is a very precarious and dangerous place to work,鈥 says Hogan.
Instead of deploying human researchers for this task, the GRAIL project will use a fleet of autonomous submarines and aerial drones, ranging in size from 4 metres to 1 metre in length, to take measurements when the first expedition begins in 2026. The vehicles are being fine-tuned with additional sensors and software to enable them to operate as a network in the harsh Arctic environment. They will all be deployed simultaneously in a series of coordinated missions at two specific glaciers, using the UK鈥檚 polar research vessel, RSS Sir David Attenborough, as an expedition mothership, says Hogan. 鈥淚t鈥檚 a new way of working,鈥 she says.
The scale of the project is 鈥渞emarkable鈥 says at the University of Sheffield, UK, who isn鈥檛 involved in GRAIL. 鈥淭here鈥檚 certainly a lot of scientific power in being able to apply everything at once,鈥 he says. But he warns the research effort will be technically challenging, particularly given the extent of the equipment involved. 鈥淚t鈥檚 logistically very complex to get all of that to work at the same time, in the same place, in an incredibly remote location,鈥 he says.
If successful, the data collected on the expedition will be analysed and fed into the state-of-the-art climate models scientists rely on to predict sea level rise and the risk of the AMOC shutdown. The team expects the data to have a 鈥渞eal impact鈥 on climate model outputs, says Hogan.
The GRAIL findings will also contribute to a wider ARIA initiative to , which could provide advance alerts of major, irreversible changes in Earth systems.