NEW EVIDENCE OF SYNCHRONEITY BETWEEN DEGLACIATION OF THE UINTA
MOUNTAINS AND THE FALL OF LAKE
BONNEVILLE
LAABS,
Benjamin J.C., MUNROE, Jeffrey S.2,
SHAKUN, Jeremy D.2, and CAFFEE, Marc3, (1) Department of Geology and Geophysics, University
of Wisconsin-Madison, 1215 W. Dayton St, Madison, WI 53706,
blaabs@gustavus.edu, (2) Geology Department, Middlebury College, Bicentennial
Hall, Middlebury, VT 05753, (3) Physics, Purdue Univ,
W. Lafayette, IN 47906
Field-based reconstructions
of Pinedale-age glaciers in the Uinta Mountains show that equilibrium line
altitudes (ELAs) rose ~600 meters from west to east across the glaciated part
of range, and that the steepest rise in ELA occurred in the westernmost 80
km. The ELA gradient across the Uintas is greater than the regional east-west
ELA gradient documented in previous studies, and suggests that, given a uniform
temperature depression, precipitation in the western Uintas was enhanced
relative to eastern (and downwind) parts of the range during the Last Glacial
Maximum (LGM). Previous studies along with new LGM-glacier
reconstructions presented here suggest that Lake Bonneville
provided moisture to valleys in the western Uintas; this inference is supported
by a recently developed chronology of glacial deposits in the south-central Uintas.
The youngest of thirteen acceptable 10Be cosmogenic surface-exposure ages of moraine boulders indicates that
glaciers in the Lake Fork and Yellowstone canyons maintained their maximum
extents until as late as 16.1 ± 0.9 ka (based on a 10Be production rate of 5.1 atoms g SiO2-1 yr-1 at high latitude and sea level
scaled for site elevation and latitude), up to ~2000 years later than glaciers
in the Wind River range and the Colorado Rocky Mountains.
Calendar-year-corrected radiocarbon ages from Oviatt (1997)
and more recent studies indicate that Lake Bonneville
fluctuated about its hydrologic maximum until ca. 16 ka and possibly
later. Despite potential uncertainties in comparing radiocarbon and
cosmogenic 10Be exposure ages, deglaciation
in the south-central Uinta Mountains and the hydrologic fall of Lake Bonneville
from the Provo
shoreline were approximately synchronous. Furthermore, the steep ELA
gradient provides evidence for a causal relationship between Lake Bonneville
and glaciers in the western Uinta Mountains.