Prediction of alpine glacier sliding instabilities: a new hope

TL;DR

This paper presents a new numerical model to predict glacier sliding instabilities by analyzing geometrical configurations, drainage networks, and recoupling phenomena, offering hope for improved early warning of glacier break-offs.

Contribution

The study introduces a novel numerical model that simulates gravitational and hydrological processes to predict glacier sliding instabilities and potential break-offs.

Findings

Critical geometrical configurations influence instability onset

Distributed drainage networks are key to catastrophic break-offs

Recoupling of glacier to bed may serve as a precursory sign

Abstract

Mechanical and sliding instabilities are the two processes which may lead to breaking off events of large ice masses. Mechanical instabilities mainly affect unbalanced cold hanging glaciers. For the latter case, a prediction could be achieved based on data of surface velocities and seismic activity. The case of sliding instabilities is more problematic. This phenomenon occurs on temperate glacier tongues. Such instabilities are strongly affected by the subglacial hydrology: melt water may cause (i) a lubrication of the bed and (ii) a decrease of the effective pressure and consequently a decrease of basal friction. Available data from Allalingletscher (Valais) indicate that the glacier tongue experienced an active phase during 2-3 weeks with enhanced basal motion in late summer in most years. In order to scrutinize in more detail the processes governing the sliding instabilities, a numerical model developed to investigate gravitational instabilities in heterogeneous media was applied to Allalingletscher. This model enables to account for various geometric configurations, interaction between sliding and tension cracking and water flow at the bedrock. We could show that both a critical geometrical configuration of the glacier tongue and the existence of a distributed drainage network were the main causes of this catastrophic break-off. Moreover, the analysis of the modeling results diagnose the phenomenon of recoupling of the glacier to its bed as a potential new precursory sign announcing the final break-off. This model casts a gleam of hope for a better understanding of the ultimate rupture of such glacier sliding instabilities.