A modified viscous flow law for natural glacier ice: Scaling from laboratories to ice sheets

Author(s)

Ranganathan, Meghana; Minchew, Brent

Abstract

Glacier flow modulates sea level and is governed largely by the viscous deformation of ice. Multiple molecular-scale mechanisms facilitate viscous deformation, but it remains unclear how each contributes to glacier-scale deformation. Here, we present a model of ice deformation that bridges laboratory and glacier scales, unifies existing estimates of the viscous parameters, and provides a framework for estimating the parameters from observations and incorporating flow laws derived from laboratory observations into glacier-flow models. Our results yield a map of the dominant deformation mechanisms in the Antarctic Ice Sheet, showing that, contrary to long-standing assumptions, dislocation creep, characterized by a value of the stress exponent, likely dominates in all fast-flowing areas. This increase from the canonical value of dramatically alters the climate conditions under which marine ice sheets may become unstable and drive rapid rates of sea-level rise.

Date issued

2024-05-30

URI

https://hdl.handle.net/1721.1/155148

Department

Massachusetts Institute of Technology. Department of Earth, Atmospheric, and Planetary Sciences

Publisher

Proceedings of the National Academy of Sciences

Citation

Ranganathan, Meghana and Minchew, Brent. 2024. "A modified viscous flow law for natural glacier ice: Scaling from laboratories to ice sheets." 121 (23).

Version: Final published version

ISSN

0027-8424

1091-6490