|2004 Denver Annual Meeting (November 7–10, 2004)|
|Paper No. 118-13|
|Presentation Time: 1:30 PM-5:30 PM|
DYNAMICS OF COLD-AIR FLOW FROM TALUS AT THE ICE MOUNTAIN ECOLOGICAL REFUGIUM, WEST VIRGINIA, USA
KITE, J. Steven1, ANDREWS, Kevin M.2, KITE, Susan C.3, and WILSON, Tom1, (1) Department of Geology and Geography, West Virginia Univ, PO Box 6300, Morgantown, WV 26506, firstname.lastname@example.org, (2) Marshall Miller & Associates, Route 720, Bluefield Industrial Park, Bluefield, VA 24605, (3) West Virginia Geological and Economic Survey, 1 Mont Chateau Rd, Morgantown, WV 26508|
Cold-air flow from 50 to 75 small vents at Ice Mountain Ecological Preserve supports five rare plant species at ~235 m above sea level that are not known below 900 m elevation elsewhere in the Central Appalachians. Existence of the paleo-refugium suggests cold air flow from the talus may have operated without significant interruption since the early Holocene.
Terrain conductivity and VLF surveys indicate the talus is exceptionally thick (8 to 20 m) compared to others in the region. Talus boulders are derived from upper Helderberg and Oriskany sandstone atop Ice Mountain, but are underlain by Devonian Millboro Shale. All cold-air vents occur on a fluvially truncated convex toe-slope, a morphology contrasting concave toe-slopes typical of most Appalachian talus. Upper and middle talus surfaces are open with little impedance of air flow except spotty vegetation cover. Vegetation and “soil” cover is more continuous along the convex toe-slope, restricting basal drainage of cold dense air to the small vents, which have a cumulative opening area of only 5 to 20 sq. m.
One year of hourly and bi-hourly temperature measurements indicates that cold-air vents are fed by high-density cold air trapped within the thick boulder accumulation. Mean vent temperatures (3 degrees C) are 7 degrees colder than mean air temperatures on the upper talus. Vent air warms very gradually at the onset of spring. In contrast, cold nights in late summer to mid-winter produced sudden vent temperature drops of 5 degrees or more in an hour, suggesting complete exchange of air whenever the air is colder and denser above the talus than within. Air temps rise within a day of exchange events, but typically stabilize 1 or 2 degrees less than pre-exchange temperatures.
Ice and snow may accumulate deep within the talus during winter months, but year-round ice persistence is not essential to summer cold-air flow. Winter-ice accumulations at two instrumented vents melted during late April 2004.
2004 Denver Annual Meeting (November 7–10, 2004)
General Information for this Meeting
|Session No. 118--Booth# 19|
Colorado Convention Center: Exhibit Hall
1:30 PM-5:30 PM, Monday, 8 November 2004
Geological Society of America Abstracts with Programs, Vol. 36, No. 5, p. 283
© Copyright 2004 The Geological Society of America (GSA), all rights reserved. Permission is hereby granted to the author(s) of this abstract to reproduce and distribute it freely, for noncommercial purposes. Permission is hereby granted to any individual scientist to download a single copy of this electronic file and reproduce up to 20 paper copies for noncommercial purposes advancing science and education, including classroom use, providing all reproductions include the complete content shown here, including the author information. All other forms of reproduction and/or transmittal are prohibited without written permission from GSA Copyright Permissions.