2014 GSA Annual Meeting in Vancouver, British Columbia (19–22 October 2014)

Paper No. 163-2
Presentation Time: 1:15 PM

TIDEWATER GLACIER DYNAMICS ON THE ANTARCTIC PENINSULA


PETTIT, Erin C., University of Alaska Fairbanks, Department of Geology and Geophysics, Fairbanks, AK 99775, SCAMBOS, Ted A., National Snow and Ice Data Center/CIRES, University of Colorado, 1540 30th Street, Rm 218, Campus Box 449, Boulder, CO 80309-0449, HARAN, Terry, National Snow and Ice Data Center/CIRES, University of Colorado, 1540 30th Street, Rm 218, Campus Box 449, Boulder, CO 80309, WELLNER, Julia Smith, Department of Geosciences, University of Houston, 312 Science & Research Building 1, Houston, TX 77204-5007, DOMACK, Eugene, College of Marine Science, University of South Florida, 140 7th Avenue South, St. Petersburg, FL 33701, VERNET, Maria, Integrative Oceanography Division, Mail Code 0218, Scripps Institution of Oceanography, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093, LEVENTER, Amy, Geology, Colgate University, 13 Oak Drive, Hamilton, NY 13346 and ISHMAN, Scott, Department of Geology, Southern Illinois University, Carbondale, IL 62901

The northern Antarctic Peninsula (nAP, north of 66°S) exhibits an extreme west-to-east precipitation gradient resulting from the effect of its narrow north-south ridge extending transverse across the prevailing westerly winds of the Southern Ocean. Snowfall on the west side of the AP is one to two orders of magnitude higher than the east side. This gradient drives short, steep, fast-flowing glaciers into narrow fjords on the west side, while longer lower-sloping glaciers flow down the east side into broader fjord valleys. This pattern in ice dynamics affects ice–ocean interaction on timescales of decades to centuries, and shapes the subglacial topography and submarine bathymetry on timescales of glacial cycles. In our study, we calculate ice flux for the western and eastern nAP using a drainage model that incorporates the modern ice surface topography, the RACMO-2 precipitation estimate, and recent estimates of ice thinning. Our results, coupled with observed rates of ice velocity from InSAR (I. Joughin, personal communication) and Landsat 8 -derived flow rates (this study), provide an estimate of ice thickness and fjord depth in grounded-ice areas for the largest outlet glaciers. East-side glaciers either still terminate in or have recently terminated in ice shelves. Sedimentary evidence from the inner fjords of the western glaciers indicates they had ice shelves during LIA time, and may still have transient floating ice tongues (tabular berg calvings are observed). Although direct oceanographic evidence is limited, the high accumulation rate and rapid ice flux implies cold basal ice for the western nAP glaciers and therefore weak subglacial discharge relative to eastern nAP glaciers and other tidewater fjord systems such as in Alaska. Finally, despite lower accumulation rates on the east side, the large elongate drainage basins result in a greater ice flux funneled through fewer deeper glaciers. Due to the relation between ice flux and erosion, these east-side glaciers have longer and deeper fjords than the west-side glaciers. These distinct differences between the glaciers of the west and east side of the AP exert a primary control on the differing ice-ocean interactions, grounding-line retreat, and subglacial erosion rates, and provide context to understand rates of nAP ice mass loss.