Abstract
Glaciers in High Mountain Asia are an important freshwater resource for large populations living downstream who rely on runoff for hydropower, irrigation, and municipal use. Projections of glacier mass change and runoff therefore have important socio-economic impacts. In this study, we use a new dataset of geodetic mass balance observations of almost all glaciers in the region to calibrate the Python Glacier Evolution Model (PyGEM) using Bayesian inference. The new dataset enables the model to capture spatial variations in mass balance and the Bayesian inference enables the uncertainty associated with the model parameters to be quantified. Validation with historical mass balance observations shows the model performs well and the uncertainty is well captured. Projections of glacier mass change for 22 General Circulation Models (GCMs) and four Representative Concentration Pathways (RCPs) estimate that by the end of the century glaciers in High Mountain Asia will lose between 3311% (RCP2.6) and 689% (RCP8.5) of their total mass relative to 2015. Considerable spatial and temporal variability exists between regions due to the climate forcing and glacier characteristics (hypsometry, ice thickness, elevation range). Projections of annual glacier runoff reveal most monsoon-fed river basins (Ganges, Brahmaputra) will hit a maximum (peak water) prior to 2050, while the Indus and other westerlies-fed river basins will likely hit peak water after 2050 due to significant contributions from excess glacier meltwater. Monsoon-fed watersheds are projected to experience large reductions in end-of-summer glacier runoff. Uncertainties in projections at regional scales are dominated by the uncertainty associated with the climate forcing, while at the individual glacier level, uncertainties associated with model parameters can be significant.
Highlights
High Mountain Asia has the largest coverage of glaciers outside of the polar regions
The major advance in this study is the application of a Bayesian model (Rounce et al, 2020) to calibrate every glacier in High Mountain Asia and quantify the uncertainty associated with the model parameters
The basin averaged increases in annual glacier runoff when peak water occurs can be substantial, e.g., in the Tarim basin glacier runoff increases by ∼80% of the initial glacier runoff, while glacier runoff on the Tibetan Plateau and Amu Darya increase by more than 50%
Summary
High Mountain Asia has the largest coverage of glaciers outside of the polar regions The meltwater from these glaciers provides valuable freshwater for hydropower, irrigation, and municipal use to people living downstream (Biemans et al, 2019; Pritchard, 2019). Circulation Models (GCMs) and Representative Concentration Pathways (RCPs) estimate by 2100 the glaciers could lose 45 ± 8% (RCP 2.6) to 69 ± 14% (RCP 8.5) of their total mass relative to 2015 (Hock et al, 2019). These results are consistent with projections from Kraaijenbrink et al (2017). Advancing our understanding of the timing and quantity of peak water is crucial for assisting regional water resources planning and management
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