Abstract
Abstract. Energy exchanges between the atmosphere and the glacier surface control the net energy available for snow and ice melt. This paper explores the response of a midlatitude glacier in the Canadian Rocky Mountains to daily and interannual variations in the meteorological parameters that govern the surface energy balance. We use an energy balance model to run sensitivity tests to perturbations in temperature, specific humidity, wind speed, incoming shortwave radiation, glacier surface albedo, and winter snowpack depth. Variables are perturbed (i) in isolation, (ii) including internal feedbacks, and (iii) with co-evolution of meteorological perturbations, derived from the North American regional climate reanalysis (NARR) over the period 1979–2014. Summer melt at this site has the strongest sensitivity to interannual variations in temperature, albedo, and specific humidity, while fluctuations in cloud cover, wind speed, and winter snowpack depth have less influence. Feedbacks to temperature forcing, in particular summer albedo evolution, double the melt sensitivity to a temperature change. When meteorological perturbations covary through the NARR forcing, summer temperature anomalies remain important in driving interannual summer energy balance and melt variability, but they are reduced in importance relative to an isolated temperature forcing. Covariation of other variables (e.g., clear skies, giving reduced incoming longwave radiation) may be partially compensating for the increase in temperature. The methods introduced in this paper provide a framework that can be extended to compare the sensitivity of glaciers in different climate regimes, e.g., polar, maritime, or tropical environments, and to assess the importance of different meteorological parameters in different regions.
Highlights
Glaciers and ice fields are thinning and retreating in all of the world’s mountain regions in response to global climate change (e.g., Marzeion et al, 2014)
Radiation fluxes and albedo values are from automatic weather station measurements and the turbulent fluxes and subsurface heat conduction are modelled from the AWS data
We examine the sensitivity of net summer energy balance and melt to interannual variations in each weather variable in the North American regional climate reanalysis (NARR) forcing
Summary
Glaciers and ice fields are thinning and retreating in all of the world’s mountain regions in response to global climate change (e.g., Marzeion et al, 2014). Latent heat fluxes are a significant source of energy in maritime and tropical environments (Wagnon et al, 1999, 2003; Favier et al, 2004; Anderson et al, 2010), and their strength is a function of humidity and wind conditions, which are not strongly correlated with temperature fluctuations This calls for a broader exploration of glacier sensitivity to climate variability and change, beyond just the influence of temperature. Variations in net shortwave radiation, sensible heat flux, and temperature each contribute to differences in glacier sensitivity to climate variability between these locations We build on these studies through a systematic examination of glacier energy balance and melt sensitivity. We examine the summer energy balance and evaluate the impact of different variables in isolation and with more realistic covariance of meteorological conditions
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