Located in the Brabazon Range of southeastern Alaska, Yakutat Glacier is one of the fastest retreating glaciers in the world. It is the primary outlet for the 810-square kilometer (310-square mile) Yakutat ice field, which drains into Harlequin Lake and, ultimately, the Gulf of Alaska.
Landsat satellites captured this pair of images showing changes in the glacier and lake. The Thematic Mapper on Landsat 5 acquired the top image on August 22, 1987; the Operational Land Imager on Landsat 8 captured the bottom image on August 13, 2013. Snow and ice appear white and forests are green. The brown streaks on the glaciers are lateral and medial moraines.
Over the past 26 years, the glacier’s terminus has retreated more than 5 kilometers (3 miles). What is causing the rapid retreat? University of Alaska glaciologist Martin Truffer and colleagues pointed to a number of factors in their 2013 study published in the Journal of Glaciology. The chief cause is the long-term contraction of the Yakutat Ice Field, which has been shrinking since the height of the Little Ice Age.
Once part of a much larger ice field, Yakutat has been contracting for hundreds of years. As other nearby glaciers retreated, Yakutat ice field was cut off from higher-elevation areas that once supplied a steady flow of ice from the north. With that flow cut off, there simply is not enough snow falling over the low-elevation Yakutat ice field to prevent it from retreating.
Beyond this natural change, human-caused global warming has hastened the speed of the retreat. Between 1948–2000, mean annual temperatures in Yakutat increased by 1.38° Celsius (2.48° Fahrenheit). Between 2000 and 2010, they rose by another 0.48°C (0.86°F). The warmer temperatures encourage melting and sublimation at all ice surfaces exposed to the air.
In the past few years, the breakdown of a long, floating ice tongue has triggered especially dramatic changes in the terminus of Yakutat glacier. For many years, Yakutat’s two main tributaries merged and formed a 5-kilometer (3-mile) calving face that extended far into Harlequin Lake. In the past decade, satellites observed a rapid terminus retreat and the breakup of the ice tongue in 2010. As a result, the calving front divided into two sections, with one running east-west and another running north-south. See Truffer’s blog for photos and field updates.
“You can’t just look at the rapid retreat you see in these images and say that it is entirely natural or entirely due to human-caused global warming,” explained Truffer. “It’s a combination of both.”
References and Related Reading
- Berthier, E. et al (2010, January 17) Contribution of Alaskan glaciers to sea-level rise derived from satellite imagery. Nature Geoscience, (3) 92-95.
- Blackwelder, E. et al (1907) Glacial Features of the Alaskan Coast between Yakutat Bay and the Alsek River. Journal of Glaciology, 15 (5).
- Truffer, M. (2010, May 25) Yakutat Glacier. Accessed August 12, 2014.
- Truffer, M. (2010, August 29) Yakutat Glacier again. Accessed August 12, 2014.
- Truffer, M. (2011, May 30) Yakutat Glacier, still falling apart. Accessed August 12, 2014.
- Truffer, M. (2011, October 2) Yakutat Glacier, the end of a project. Accessed August 12, 2014.
- Truffer, M. (2014, June 2) Yakutat Glacier, a glaciologist’s paradise. Accessed August 12, 2014.
- Molina, B.F. (2008) Glaciers of Alaska: Satellite Image atlas of glaciers of the world. U.S Geological Survey Professional Paper, 1386-K, 525.
- Pelto, M. (2009, December 5) Yakutat Glacier Rapid Retreat, Alaska. Accessed August 7, 2014.
- Radiolab (2014, January 31) A Hunk Of Planet Dissolves Before Our Eyes. Accessed August 12, 2014.
- Trüssel, B. et al. (2013) Rapid thinning of lake calving Yakutat Glacier and the collapse of the Yakutat Icefield, Southeast Alaska. Journal of Glaciology, 59 (213), 149-161.