Temperature index modeling of the Kahiltna Glacier: comparison to multiple field and geodetic mass balance datasets

Thesis (M.S.) University of Alaska Fairbanks, 2013 Glaciers of Alaska, USA, and Northwestern Canada are shedding mass at one of the highest rates of any mountain glacier system, with significant impact at the global and local scales. Despite advances in satellite and airborne technologies, fully cha...

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Bibliographic Details
Main Author: Young, Joanna
Other Authors: Arendt, Anthony, Hock, Regine, Motyka, Roman
Format: Thesis
Language:English
Published: 2013
Subjects:
Fairbanks
Canada
alaska range
glacier
glacier*
glaciers
Alaska
Online Access:http://hdl.handle.net/11122/4477
Description
Summary:Thesis (M.S.) University of Alaska Fairbanks, 2013 Glaciers of Alaska, USA, and Northwestern Canada are shedding mass at one of the highest rates of any mountain glacier system, with significant impact at the global and local scales. Despite advances in satellite and airborne technologies, fully characterizing the temporal evolution of glacier mass change in individual watersheds remains a challenge. Temperature index modeling is an approach that can be used to expand on sparse ground observations, and that can help bridge the gap between regional and individual watershed estimates of the time series of glacier mass change. Here we present a study on temperature index modeling of glacier-wide mass balance for the large Kahiltna Glacier (502 km�_, 270 to 6100 m in elevation) in the Central Alaska Range, using a combination of ground observations and past climate data products. We reproduce mass changes from 1991 to 2011, and assess model performance by comparing our results to several field and remote sensing datasets. First, we compare our results to a 20-year record of mass balance measurements at a National Park Service index site at the glacier's equilibrium line altitude. We find low correlation between index site measurements and modeled glacier-wide balances (R�_ = 0.24), indicating that the index site may not be representative of the glacier-wide mass balance regime. We compare next to glacier-wide mass balances derived from airborne laser altimetry, to assess the model's long-term mass change estimates. We find disagreement between the mean annual balances for 1995 to 2010 (-0.95 �0.49 m w.e. yr����_ from the model versus -0.69 +0.07/-0.08 m w.e. yr����_ from laser altimetry). To validate the laser altimetry methods, we then compare estimates from 1951 to 2011 from laser altimetry and digital elevation model differencing, finding close agreement (-0.48 +0.08/-0.09 m w.e. yr����_ and -0.41 �0.26 m w.e. yr����_, respectively), and lending strength to the laser altimetry centerline extrapolation ...

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