Almost 800 subglacial lakes catalogued for first time in new global inventory

The world’s first inventory of subglacial lakes has been compiled by an international team led by the University of Sheffield, providing a comprehensive directory of where the lakes are and how they are changing in a warming climate.

A snowmobile travelling across Antarctica with a radar survey attached to locate and examine subglacial lakes
Ice penetrating radar survey to locate and examine subglacial lakes. Taken in Antarctica in 2020 by Dr Kate Winter
  • An international team of researchers led by Dr Stephen Livingstone from the University of Sheffield has now catalogued data on hundreds of subglacial lakes in Antarctica, Greenland and Iceland, as well as in glacial valley regions such as the Alps.
  • Subglacial lakes can influence the speed at which ice flows into oceans and can cause flooding and landslides in mountainous regions.
  • Some of the lakes are under thousands of metres of ice, and can harbour unique life forms.
  • The 773 lakes catalogued in the inventory include 59 which have been newly identified in Antarctica - some of which measure up to six miles in length.

The world’s first inventory of subglacial lakes has been compiled by an international team led by the University of Sheffield, providing researchers with a comprehensive directory of where the lakes are and how they are changing in a warming climate.

Subglacial lakes can form underneath ice sheets or glacial valley regions. They can play a critical role in the speed at which ice flows into oceans and, when on land in mountainous regions, could pose a major risk to populations downstream if they were to drain and cause flooding and landslides.

It is believed that there are many thousands of subglacial lakes worldwide but, until now, their details were not collectively held and there was no clear picture on the size, stability and characteristics of the lakes.

An international team of researchers led by Dr Stephen Livingstone, from the University of Sheffield’s Department of Geography, has now catalogued data on almost 800 lakes in Antarctica, Greenland and Iceland, as well as in glacial valley regions such as the Alps.

The inventory, which has just been published in the Nature Reviews journal Earth & Environment, details the lake environments and dynamics, their size, how they behave and the impact on their local area.

The inventory provides a knowledge base of the current status and location of the lakes, allowing scientists to assess any future changes as the climate warms.  It also highlights the gaps in collective knowledge that will help researchers to focus on new areas in future.

While 80 per cent of the lakes were found to be stable – meaning they have no addition or removal of water at all, or they have a balanced inflow and outflow – the researchers also observed that 20 per cent of lakes are active. This means they can drain suddenly and catastrophically, posing a hazard to human populations and infrastructure downstream.

An aerial photo of Antarctica, showing a snowmobile with a radar survey attached to locate and examine subglacial lakes
Taken in Antarctica in 2020 by Dr Kate Winter

Geophysical data currently available mean that the majority of lakes included in the inventory are in Antarctica. The researchers have called for future studies to focus on valley glaciers, ice caps and the Greenland Ice Sheet to gain a better understanding of water storage and drainage beneath glaciers in vulnerable areas.

Dr Stephen Livingstone, lead author of the inventory from the University of Sheffield’s Department of Geography, said: “Innovations in radio-echo sounding, swath radar technology, satellite altimetry and high-resolution time-stamped digital surface models have confirmed the widespread existence of subglacial lakes over the last five decades.

“Our inventory will enable researchers to evaluate subglacial lake environments and their dynamics across different regions. As the ice above subglacial lakes responds to climate change, lakes which were once stable may become unstable, and vice versa.

“Now we have a better understanding of how many lakes are currently stable, we can monitor how this changes with time. These changes are not just important for water and ice flow, but also for the lifeforms that exist in the lakes.”

Dr Kate Winter, Senior Lecturer in Northumbria University’s Department of Geography and Environmental Sciences, said: “Subglacial lakes are fascinating. They can occur due to meltwater from the surface of the glacier travelling to the base and lying in in hollow areas or cavities, or they can occur due to geothermal heating from the earth below, warming the ice above and causing it to melt.

“The lakes are protected by a layer of thick overlying ice which insulates it from the cold air above, preventing them from re-freezing and can exist alone for millions of years, harbouring unique life forms, or they can fill and drain over hourly timescales.

“These lakes can lubricate the base of the glacier or ice sheet and make ice flow faster, contributing to global sea level rise. In populated regions such as the Alps, the sudden release of subglacial lake water can cause catastrophic damage to life and infrastructure.

“It is therefore important to study where subglacial lakes are, how much water they contain, how stable or active they may be and how they might be changing over time so we can learn more about why they form and what influence they may have on the local area.”

The 773 lakes catalogued in the inventory include 59 which have been newly identified in Antarctica - some of which measure up to six miles in length and are under 3,000 metres of ice.

The paper Subglacial lakes and their changing role in a warming climate is now available in Nature Earth & Environment.


Contact

For further information please contact:

Centres of excellence

The University's cross-faculty research centres harness our interdisciplinary expertise to solve the world's most pressing challenges.