Sequence Stratigraphy and Detrital Zircon Geochronology of Middle-Late Ordovician Mt. Wilson Quartzite, British Columbia, Canada

Hutto, Andrew Paul

2012 May 1900

Middle-Late Ordovician Mt. Wilson Quartzite, southern British Columbia, Canada, is a supermature quartz arenite deposited in shallow marine-marginal marine environments on the Early Paleozoic western Laurentian passive margin. Facies-stacking patterns indicate the Mt. Wilson Quartzite is an unconformity bounded, 2nd-order depositional sequence, containing two 3rd-order sequences, and numerous parasequences. Detrital zircon age spectra of six samples of the Mt. Wilson Quartzite have numerous peaks that are unique to Middle to Late Ordovician quartz arenites of western Laurentia. The main peaks, 1800-2000 Ma, 2000-2200 Ma, and 2300-2400 Ma are interpreted to have been derived from basement rocks that were exposed east of the study area: Trans-Hudson Orogeny (1800-2000 Ma), Taltson Orogen (1800-2000 Ma), Buffalo Head Terrane (2000-2400 Ma), Paleoproterozoic crust (2000-2400 Ma), and the Wopmay Terrane (2000-2400 Ma). It is likely that these areas were sourced by local rivers and tributaries draining the Transcontinental Arch and delivered sediment to the deposition location of the Mt. Wilson Quartzite. While longshore transport was a viable distribution method for sediment along the passive margin, it is unlikely that the Peace River Arch (located northwest of the Mt. Wilson Quartzite) was its sole point source; rather it is more likely that there were multiple sediment sources for these western Laurentian quartz arenites. Temporal changes in provenance indicate different areas of basement rock were exposed throughout the deposition of the Mt. Wilson Quartzite, most likely reflecting long-term flooding of North America. The potential for spatial changes in provenance remains unsolved.

Ordovician

Quartzite

Quartz Arenite

Sequence Stratigraphy, Detrital Zircon

Mt. Wilson

Detrital Zircon Geochronology of Middle Ordovician Siliciclastic Sediment on the Southern Laurentian Shelf

Pickell, Michael

14 March 2013

Middle Ordovician (Whiterockian) sandstone units within the Oil Creek, McLish, and Tulip Creek formations of the Simpson Group of Oklahoma, and the Everton (Calico Rock Member) and St. Peter formations of Arkansas were deposited on the southern margin of Laurentia. They represent the first major siliciclastic input to the southern U.S. Midcontinent above the post-Sauk unconformity. Samples were collected from outcrops of the major sandstone units to determine their U-Pb detrital zircon age distributions for provenance. Samples were prepared and analyzed using laser ablation - inductively coupled plasma - mass spectrometry (LA-ICP-MS). Probability-density plots were created to determine likely source areas for sediment, based on comparing detrital zircon ages to known ages of basement terranes. Detrital zircon grains from the Early Whiterockian Calico Rock sandstone indicate a majority of its zircon population was ultimately derived from the 900-1300 Ma Grenville orogenic province, with secondary input ultimately derived from the 1300-1550 Ma Granite-Rhyolite/Anorogenic Province and the Archean Superior province along the Transcontinental Arch. It is likely, at this time, that zircons were also sourced from reworked sediments from more proximal secondary sources. With sea level rise and transgression, the depositional shoreline and the sediment source areas moved to the north and west. The basal Oil Creek Sandstone of the Simpson Group was deposited unconformably above the Arbuckle Group in southern Oklahoma, and its zircon population is dominated by grains from Archean source terranes along the Transcontinental Arch. The basal sandstone unit of the McLish Formation indicates renewed sediment input containing zircons from 1300-1550 Ma Granite-Rhyolite/Anorogenic and 1600-1700 Ma Yavapai-Mazatzal terranes along the Transcontinental Arch. The Nemaha Ridge in northeastern Kansas likely acted as a source of first-cycle sediment in the southern midcontinent during this time. Small populations of detrital zircon grains between 1800 Ma and 2000 Ma occur in the majority of the samples. Their probability density peaks are generally centered at roughly 1850 Ma, suggesting an ultimate source in the Penokean orogenic province along the Transcontinental Arch.

quartz arenite

Everton Formation

St. Peter Formation

Simpson Group

Detrital zircon

Ordovician

Distribution and Transport of Water in Natural Quartz Arenites Near Brittle-Ductile Transition Conditions

VanDeVelde, Sharon Ann

15 April 2009

No description available.

Geology

quartz arenite

brittle-ductile transition

FTIR

water

novaculite

dehydration

rehydration

exchange

diffusion

mechanical deformation

chemical deformation

Tuscarora Sandstone