Total Organic Carbon Variability In The Utica Shale Of Northwest Ohio PDF Download

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Total Organic Carbon Variability in the Utica Shale of Northwest Ohio

Total Organic Carbon Variability in the Utica Shale of Northwest Ohio
Author: Kyle J. Cox
Publisher:
Total Pages: 62
Release: 2012
Genre:
ISBN:
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Abstract: The Utica Shale is an Ordovician age rock unit found throughout most of Ohio and much of the Northeastern United States. Recently, the Utica's potential as a source and reservoir for hydrocarbons (oil and natural gas) has become an important topic in Ohio. If the Utica contains large amounts producible of oil and gas, the economic impact on the state could be very significant. Due to its hydrocarbon generating potential, there is a great amount of ongoing research focusing on the Utica. Most of this investigation targets the Utica in Eastern Ohio since geologic factors in the area (history of oil and gas production, the unit resides within a window of ideal formation depth below the surface) and preliminary explorations indicate a high likelihood that producible amounts of hydrocarbon reside in the formation in that part of the state. Similar factors (though not as ideal) may exist in the Northwestern portion of the state, however little research has considered this area. The purpose of this study was to investigate the hydrocarbon potential of the Utica Shale in Northwestern Ohio by measuring TOC values of rock samples from the area, and investigating how these values vary throughout the area. Total Organic Carbon, more commonly referred to as TOC, is one important indicator of a geologic units potential as a source rock. It is a measurement of the concentration of organic material in a rock which is necessary for the generation of hydrocarbons. TOC measurements from the Utica in Northwest Ohio were obtained by acidifying rock samples from the Utica in the study area to remove Inorganic Carbon from the samples followed by combusting them in an Elemental Analyzer which measured the remaining, and thus organic, Carbon. 34 samples were obtained from 16 wells in 10 counties of Northwest Ohio. Results showed limited hydrocarbon potential for the area. The average TOC was 1.38% and the 34 samples ranged from 0.73 to 2.75% TOC with the majority of samples falling between 1 and 2%. No strong trends in the variability of the TOC by location were identified. Future research following the same methodology with a larger sample area or a closer-spaced sample frequency across the study area could reveal trends that were too broad or narrow to be identified by measuring the sampled wells.

Directory of Geoscience Departments 2015

Directory of Geoscience Departments 2015
Author: Carolyn Wilson
Publisher: American Geosciences Inst
Total Pages: 2140
Release: 2015-02-27
Genre: Reference
ISBN:
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The Directory of Geoscience Departments 50th Edition is the most comprehensive directory and source of information about geosciences departments and researchers available. It is an invaluable resource for individuals working in the geosciences or must identify or work with specialists on the issues of Earth, Environmental, and related sciences and engineering fields. The Directory of Geoscience Departments 50th Edition provides a state/country-sorted listing of nearly 2300 geoscience departments, research departments, institutes, and their faculty and staff. Information on contact information for departments and individuals is provided, as well as details on department enrollments, faculty specialties, and the date and source of faculty and staff's highest degree. New in the 50th edition: Listing of all US and Canadian geoscience theses and dissertations accepted in 2012 that have been reported to GeoRef Information Services, as well as a listing of faculty by their research specialty.

Organic Carbon Isotope Records of Cores from The Oatka Creek Member of The Marcellus Formation - Pennsylvania, United States

Organic Carbon Isotope Records of Cores from The Oatka Creek Member of The Marcellus Formation - Pennsylvania, United States
Author: Cihan Can
Publisher:
Total Pages:
Release: 2014
Genre:
ISBN:
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Gas from shales is growing in importance with the development of technology that allows improved natural gas production. Devonian shales from the Appalachian Basin are recognized for their significant natural gas potential. The Marcellus Shale Formation is the lowest unit of the Devonian age from Hamilton Group and consists primarily of black shales high in organic carbon. Subunits of The Marcellus Formation have been studied to assess the abundance of the organic matter and type in the shale. The Oatka Creek Member of the Marcellus Formation was chosen for this study because of its high gamma ray log response, which corresponds to increased Uranium content, and the presence of organic carbon enrichment. Few data are available on this unit because much of the focus has been on the lower part of the Marcellus Formation (The Union Springs Member). Additionally, the distinct Kačák-Otomari bioevent is thought to have had a big influence on black shale deposition globally within the interval of Oatka Creek Member's deposition. For this study, The Bald Eagle and Bilger cores of the Oatka Creek Member were analyzed to assess the effect of The Kačák-Otomari event on sedimentation in the Appalachian Basin, and to examine the organic carbon content and the sources that affected the organic carbon deposition in the cores.Total organic carbon (TOC) content and carbon stable isotopic values of The Bald Eagle and Bilger cores from Pennsylvania were determined after crushing and decarbonation steps. Based on these analyses, TOC content in the Bald Eagle Oatka Creek Member (692 to 780 ft) varies between 1.19 and 4.65 %, whereas the TOC content of the Bilger Oatka Creek Member (160 to 250 ft) varies between 0.21 and 2.8 %. The [delta]13Corg values in the Bald Eagle core have a narrow range of -29.1 to -29.9 [per mille symbol] (PDB) whereas the [delta]13Corg values for the Bilger core have a relatively wider range of -25.6 to -29.9 [per mille symbol] (PDB). The organic carbon content in the Bald Eagle core is much higher than that in the Bilger core, and the lithofacies of the Oatka Creek Member suggest less overall dilution and/or oxygenation at the location of the Bald Eagle core. Kačák-Otomari bioevent didn't have much influence in both of the cores because of the lack of significant isotopic trend excursions. Because the [delta]13Corg pattern of Bald Eagle core is uniform and depleted in BC, this study suggests the dominance of amorphous marine organic matter at that location whereas in Bilger core marine organic matter gives way upward to increasing terrestrial organic matter input indicated by the trend towards more enriched [delta]13Corg values. This study establishes a base line for the organic carbon content and stable isotopic trends of the Bald Eagle and the Bilger cores. The comparison between these two cores helps interpretations for the general characteristics of the cores and the organic carbon enrichment throughout the whole zone.

Inorganic Geochemistry of the Trenton Limestone-Utica Shale Contact Based on XRF Data

Inorganic Geochemistry of the Trenton Limestone-Utica Shale Contact Based on XRF Data
Author: Steve R. Saboda
Publisher:
Total Pages: 82
Release: 2015
Genre:
ISBN:
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The contact of the Upper Ordovician Utica Shale and underlying Trenton Limestone is normally recognized in well logs as a sharp increase in gamma-ray (GR) response, apparently reflecting the increased abundance of organic matter from the carbonate to overlying shale. Though conventional wisdom holds that organic-rich black shales can be identified by characteristic GR log signature, this may not be the case for the Utica Shale. Chemostratigraphic analysis of the Utica Shale core 75NY-2 using handheld XRF technology in tandem with a suite TOC data indicates that the Trenton-Utica contact based on GR response actually falls within the Utica Shale. Gamma-ray response principally reflects the abundance of K, Th, and especially U. Indeed, enrichment of U above crustal levels in the presence of abundant organic matter and related bacterial sulfate reduction is typical of those environments in which black shale accumulates. However, U values of the lower carbonaceous interval of the Utica Shale remain close to or even depleted relative to crustal values, essentially unchanged from those concentrations of the underlying Trenton Limestone. Of particular interest is the roughly 6m thick interval of calcareous dark black shale containing> 10% TOC at the bottom of the Utica Shale. The apparent dichotomy of elevated TOC and minimal U concentration is obvious from an artificial GR log generated from our chemostratigraphic data that displays a profile similar to GR signatures documented from Utica wells. These results suggest that the sharp increase in GR response normally recognized as the Trenton-Utica contact actually delimits the top of the organic-rich interval within the bottom of the Utica. The level at which the GR increases is observed to be the boundary of organic-rich shale and overlying organic-lean (TOC ~ 1%) grayish black shale. The contact of the organic-rich and organic-lean shale correlates with an increase of U somewhat in excess of crustal levels. Although authigenic U concentrations can be diluted by increased clastic flux, measured abundances of detrital proxies, including Al, Si, Ti, and Zr, are inconsistent with such an explanation. The U-depleted nature of the most organic-rich deposits of the Utica Shale may reflect the impress of Middle Ordovician global anoxia and consequent of drawdown of the global aqueous U inventory.

Geochemistry of the Marcellus Shale

Geochemistry of the Marcellus Shale
Author: Thomas R. Malizia
Publisher:
Total Pages: 46
Release: 2011
Genre:
ISBN:
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Gamma ray (GR) spectroscopy is commonly used to map the organic-rich facies of hydrocarbon source rocks and a constant or basin-wide correlation between GR response and total organic carbon (TOC) content is often assumed. However, in the economically significant Devonian shales of the Appalachian Basin, such as the Marcellus shale, there is a notable variability in the GR response, while TOC concentrations remain fairly consistent. GR response, which is mainly due to a decrease in uranium, is appreciably reduced in the Upper Devonian shales: Dunkirk, Pipe Creek, Rhinestreet and Middlesex, compared to that in the Marcellus shale, while TOC concentrations remain consistent. This research investigates the influence of major, minor and trace element geochemistry on the GR response of these Devonian shales. It is hypothesized that GR response may be influenced by changes in ionic abundances, particularly carbonate and phosphate, which affected the solubility, sorption, and reduction of uranium. The hypothesis is tested by systematically investigating the association of uranium with mineral and organic fractions of Marcellus shale outcroppings and core samples from the western and northern edge of the Appalachian Basin. X-ray Absorption Spectroscopy (XAS) was used to attempt to identify the valency of uranium in the shale with the greatest GR response. These results should be valuable in interpreting GR response in the Appalachian Basin and in other black shale hydrocarbon deposits.