Dynamics of the Panchi Nala glacier, western Himalaya: trends and controlling factors.

Information on glacier velocity is imperative to understand glacier mass, ice volume, topography, surge events of the glacier and response to climate change. Therefore, inter-annual surface ice velocity (SIV) of the Panchi Nala glacier has been calculated in the current study between the first two decades of the twenty-first century. To do so, the SIV has been computed by the feature tracking technique using the Co-registration of Optically Sensed Images and Correlation (COSI-Corr) method applied on the multi-temporal Landsat (TM and OLI) and sentinel -2 MSI images acquired between 2000 and 2021. The results of the study show that the mean velocity of the debris-covered tongue of the Panchi Nala Glacier is ∼10.60 ± 5.56 m/y during the study period. Additionally, the highest average glacier velocity is 13.77 ± 4.64 m/y, whereas the lowest is 8.92 ± 2.78 m/y, respectively, observed in 2005 and 2015. Also, the 95% confidence interval of the mean annual velocity lies between 9.76 and 11.43 m/y during the entire study period. The annual heterogeneity is linked with the variation of summer precipitation. Statistically, a 100 mm increment of summer precipitation can reduce the velocity around 1.3 m/y. The main reason behind this is the Panchi Nala glacier is located in high-elevation where the climate is much colder and during the summer precipitation, the lower temperatures cause the precipitation to take the form of snow, which freezes and accumulates on the glacier. This reduces the process of basal sliding. Further, detailed investigations with additional parameters need to be carried out to elucidate the comprehensive causes for inter-annual fluctuations in surface velocity. In this perspective, future research maybe directed towards higher temporal and spatial scale remote sensing-based investigations and validation of glacier surface velocity using field measurements, to better understand the glacier dynamics.Keywords: Glacier surface ice velocity; debris cover; climate change; western Himalayas.