The catastrophic release of fresh water from a vast South American lake at the end of the last Ice Age was significant enough to change circulation in the Pacific Ocean, according to new research co-authored by a PhD student from the University of Bristol.
“This study is important because we are currently concerned about the volumes of fresh water entering the oceans from the melting ice sheets in Greenland and Antarctica and this gives us an indication of the likely effects,” the study’s lead author, Professor Neil Glasser from Aberystwyth University said.
The study, published on February 12 in Scientific Reports, reveals that the lake, which was about one third the size of Wales, drained several times between 13,000 and 8,000 years ago, with devastating consequences.
At its high point the lake extended over 7,400km2, held 1500km3 of water and occupied a basin which now contains Lago General Carrera in Chile and Lago Buenos Aires in Argentina.
Held back by a dam formed by a large ice sheet, the lake drained rapidly as the ice sheet shrank in size.
Professor Glasser said: “This was a massive lake. When it drained, it released around 1150km3 of fresh water from the melting glaciers into the Atlantic and Pacific oceans – equivalent to around 600 million Olympic-sized swimming pools. This had a considerable impact on the Pacific Ocean circulation and regional climate at the time.
“Much of the freshwater drained into the sea near Golfo Peñas, south of the Chilean capital Santiago. The fresh water would have sat on top of the salt water as it spread out so it affected the regional ocean currents. The event affected the whole of southern South America and would have led to lower rainfall in winter and cooler ocean and air temperatures around Cape Horn, with the effects felt as far east as the Falkland Islands.”
The study, which applied different techniques to investigate the size of the former lake and how it drained, was undertaken by an international team of scientists, including Max Holloway, a PhD student in Bristol’s School of Geographical Sciences.
Samples of sediments deposited by the former lake were collected to determine the age of the lake drainage events using a laboratory technique known as single-grain optically stimulated luminescence dating.
Digital Elevation Models (DEMs) were applied to identify former lake shorelines and their altitudes and drainage routes and to calculate the volume of water released as the lake drained. An ocean-atmosphere climate model was used to determine the impact of dumping this amount of freshwater into the Pacific Ocean.