Revealing ‘invisible’ underwater glacier loss in Himalaya
A new study reveals that the mass loss of lake-terminating glaciers in the greater Himalaya has been significantly underestimated
The underestimation has been due to the inability of satellites to see glacier changes occurring underwater, with critical implications for the region’s future projections of glacier disappearance and water resources.
The study was conducted by an international team including researchers from the Chinese Academy of Sciences (CAS), Graz University of Technology (Austria), the University of St Andrews (UK), and Carnegie Mellon University (USA).
The researchers found that a previous assessment underestimated the total mass loss of lake-terminating glaciers in the greater Himalaya by 6.5%.
The most significant underestimation of 10% occurred in the central Himalaya, where glacial lake growth was the most rapid.
A particularly interesting case is Galong Co in this region, with a high underestimation of 65%.
See also: Ice loss from Northeastern Greenland ‘significantly underestimated’
Full extent of glacier loss
This oversight was largely due to the limitations of satellite imaging in detecting underwater changes, which has led to a knowledge gap in our understanding of the full extent of glacier loss.
From 2000 to 2020, proglacial lakes in the region increased by 47% in number, 33% in area, and 42% in volume.
This expansion resulted in an estimated glacier mass loss of around 2.7 Gt, equivalent to 570 million elephants, or over 1,000 times the total number of elephants in the world.
This loss was not considered by previous studies since the utilised satellite data can only measure the lake water surface but not underwater ice that is replaced by water.
Lead author Zhang Guoqing from the Institute of Tibetan Plateau Research, CAS, said: “These findings have important implications for understanding the impact of regional water resources and glacial lake outburst floods.”
Subaqueous mass loss
By accounting for the mass loss from lake-terminating glaciers, the researchers can more accurately assess the annual mass balance of these glaciers compared to land-terminating ones, thus further highlighting the accelerated glacier mass loss across the greater Himalaya.
The study also highlights the need to understand the mechanisms driving glacier mass loss and the underestimated mass loss of lake-terminating glaciers globally, which is estimated to be around 211.5 Gt, or roughly 12%, between 2000 and 2020.
Co-corresponding author Tobias Bolch, from Graz University of Technology, said: “This emphasises the importance of incorporating subaqueous mass loss from lake-terminating glaciers in future mass-change estimates and glacier evolution models, regardless of the study region.”
David Rounce, a co-author from Carnegie Mellon University, noted that in the long run, the mass loss from lake-terminating glaciers may continue to be a major contributor to total mass loss throughout the 21st Century as glaciers with significant mass loss may disappear more rapidly compared to existing projections.
And co-author YAO Tandong, who also co-chairs Third Pole Environment (TPE), an international science programme for interdisciplinary study of the relationships among water, ice, climate, and humankind in the region and beyond, added: “By more accurately accounting for glacier mass loss, researchers can better predict future water resource availability in the sensitive mountain region.”
The research is published in Nature Geoscience.
Image: Galong Co. © Huang Cheng.
