V43D-4929:
Palynology, geochemistry and Re-Os age of the Lower-Middle Pennsylvanian stage boundary, central Appalachian basin, USA
Thursday, 18 December 2014
Nicholas Geboy1, Gyana R Tripathy2,3, Leslie F Ruppert1, Cortland F Eble4, B. Mitch Blake5, Judith L Hannah2,6 and Holly J Stein2,6, (1)U.S. Geological Survey, Eastern Energy Resources Science Center, Reston, VA, United States, (2)Colorado State University, AIRIE Program, Fort Collins, CO, United States, (3)National Institute of Technology, Department of Earth and Atmospheric Sciences, Rourkela, India, (4)Kentucky Geological Survey, Lexington, KY, United States, (5)West Virginia Geological and Economic Survey, Morgantown, WV, United States, (6)University of Oslo, Centre for Earth Evolution and Dynamics, Oslo, Norway
Abstract:
The central Appalachian basin (CAB) in the eastern United States contains complicated sedimentary sequences often with thin and discontinuous strata. As an economically important coal-producing region, the basin’s architectural framework and depositional history are important to understand. Typically, eustatic marine incursions, marked with black shale deposits, are used for basin-wide correlation. The Betsie Shale Member of the Kanawha Formation represents one of these relatively thick and laterally extensive marine zones. This study examines the palynoflora of the Matewan coalbed, which conformably underlies the Betsie, in the context of a new Re-Os date for the Betsie Shale Member and additional geochemical measures. At its base, the Matewan contains abundant lycopsid tree spores, indicative of a submerged, flooded paleomire. Upsection, biodiversity increases to include small fern and calamite spores as well as cordaite pollen. Combined with an observed increase of inertinite, the diversification of palynoflora suggests surficial peat exposure and drying out of the paleomire. A S-rich (28 wt. %) shaley parting separates these lower and upper benches of the Matewan and may represent an initial marine pulse prior to the glacioeustatic incursion that ultimately flooded the Matewan and deposited the overlying Betsie Shale. The Betsie is organic-rich (3.05 – 4.89 wt. % TOC) with Re and Os content ranging from 320 – 1,200 ppb and 1.5 – 5.3 ppb, respectively. The highly enriched Re values result in notably high parent:daughter ratios (187Re/188Os = 3,644 – 5,737). The Re-Os isotopic data yield a Model 1 age of 323 ± 7.8 Ma (n = 7; MSWD = 0.63) with evidence that the true age lies closer to the younger end of the uncertainty. This age is consistent with previous paleontologic-based interpretations but represents the first directly measured radiometric date for the Betsie. An absolute age for the Betsie is a critical result, as the member is correlated with units in Wales and Germany and therefore has implications across the Carboniferous Euramerican Belt. Further, the Betsie has been interpreted to represent the Lower-Middle Pennsylvanian stage boundary in North America, making this directly measured age an important marker not only within the CAB but also for refinement of the Carboniferous timescale.