Abstract
Abstract. Viscous flow in ice is often described by the Glen flow law – a non-Newtonian, power-law relationship between stress and strain rate with a stress exponent n ∼ 3. The Glen law is attributed to grain-size-insensitive dislocation creep; however, laboratory and field studies demonstrate that deformation in ice can be strongly dependent on grain size. This has led to the hypothesis that at sufficiently low stresses, ice flow is controlled by grain boundary sliding, which explicitly incorporates the grain size dependence of ice rheology. Experimental studies find that neither dislocation creep (n ∼ 4) nor grain boundary sliding (n ∼ 1.8) have stress exponents that match the value of n ∼ 3 in the Glen law. Thus, although the Glen law provides an approximate description of ice flow in glaciers and ice sheets, its functional form is not explained by a single deformation mechanism. Here we seek to understand the origin of the n ∼ 3 dependence of the Glen law by using the “wattmeter” to model grain size evolution in ice. The wattmeter posits that grain size is controlled by a balance between the mechanical work required for grain growth and dynamic grain size reduction. Using the wattmeter, we calculate grain size evolution in two end-member cases: (1) a 1-D shear zone and (2) as a function of depth within an ice sheet. Calculated grain sizes match both laboratory data and ice core observations for the interior of ice sheets. Finally, we show that variations in grain size with deformation conditions result in an effective stress exponent intermediate between grain boundary sliding and dislocation creep, which is consistent with a value of n = 3 ± 0.5 over the range of strain rates found in most natural systems.
Highlights
Glaciers and ice sheets deform via gravity-driven viscous flow
We used the wattmeter (Austin and Evans, 2007, 2009) to calculate the balance between the mechanical work required for grain growth and for dynamic grain size reduction
Combining the wattmeter with a composite flow law for dislocation and grain boundary sliding (GBS) creep, we developed a system of coupled equations that can be used to predict grain size evolution in terms of temperature, stress, and strain rate
Summary
Glaciers and ice sheets deform via gravity-driven viscous flow. The most widely employed constitutive description of ice flow is the grain-size-independent Glen law, a power-law expression between strain rate (ε) and stress (σ ) of the form ε = Bσ n, where B is a temperature-dependent constant that embodies the Arrhenius dependence of creep. The Glen law is characterized by a stress exponent n of ∼ 3 and is based on the classic laboratory experiments of Glen (1952, 1955) and numerous subsequent experiments on coarse-grained polycrystalline ice. Applications of the Glen law to natural settings have found that it provides a reasonably good description of flow in glaciers and ice sheets (e.g., Weertman, 1983). The relationship between stress and strain rate in spreading ice shelves (Thomas, 1973; Jezek et al, 1985), as well as borehole tilt measurements in temperate glaciers (Raymond, 1973, 1980) and ice sheets (Paterson, 1983), supports the lab-derived value of n ∼ 3
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