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Nanopetrophysics of the Utica Shale, Appalachian Basin , Ohio, USA

Nanopetrophysics of the Utica Shale, Appalachian Basin , Ohio, USA
Author: Okwuosa Francis Chukwuma
Publisher:
Total Pages: 68
Release: 2019
Genre:
ISBN:
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The introduction of horizontal drilling combined with the ability to perform multiple stage hydraulic fracture treatment has enabled the oil and gas industry to explore previously unexploitable source formations, where it is estimated that 85% of the original reserves still resides. The application of these techniques provides economic gas and oil flow in extremely low porosity and permeability reservoirs. The Utica play, like the Bakken, Eagle ford, Marcellus, Haynesville, Permian and Niobrara plays are the current focus for unconventional reservoir exploration in the United States where it is estimated that shale gas and oil production from these plays would reach 80 billion cubic feet per day and 9.6 million barrels per day, respectively, by the year 2020 (EIA, 2014). However, despite these recent advances in production techniques used in stimulating tight shale reservoirs, most shale wells are still characterized by overall low recovery and steady steep decline in production typical to unconventional plays. The Utica Shale is not excluded from this, with production from this play showing an initial decline rate of 65% after its first year of production. This may be as a result of the low pore connectivity and very narrow pores that affects movement of hydrocarbon from the shale matrix to the well bore. A number of factors such as pressure volume and temperature (pvt), pore grain composition, multiphase fluid flow have been attributed to this observed phenomenon in shale reservoirs. However, researchers have not investigated the pore structure of the nanopores storing and transporting hydrocarbon.This study will evaluate pore-size distribution and pore connectivity of Utica Shale samples obtained from J. Goins (GS-3), Prudential (1-A) and Fred Barth (#3) wells in Ohio. Using mercury intrusion porosimetry, fluid (DI water, API brine and n-decane) and trace rimbibition, and edge-only accessible porosity tests, we were able to investigate the pore structure, edge accessible porosity, and the degree to which wettability is associated with mineral and organic kerogen phases. The MICP tests gave us initial sample characterization of basic petrophysical properties (porosity, permeability, pore-size distribution, and tortuosity). We examined imbibition behavior and imbibed tracer distribution for fluids (API brine or n-decane) to examine the association of tracers with mineral or kerogen phases using LA-ICP-MS mapping to measure the presence of tracersin each fluid. Mercury intrusion capillary pressure analyses shows that the Utica pores are predominantly in the nanometer size range, with measured average pore-throat diameter of 4 nm to 6 nm across the study location. Imbibition slopes shows an evidence of low pore connectivity which is consistent with percolation theory interpretation of low connectivity and may be due to the observed small pore-throat distribution. These innovative approaches are significant because they may hold the key to understanding fluid flow and pore structure in the nanopores by stipulating the limited accessibility and connectivity in the Utica Shale.

Coupled Geochemical and Nano-petrophysics of the Utica Play, Appalachian Basin, Ohio, U.S.A.

Coupled Geochemical and Nano-petrophysics of the Utica Play, Appalachian Basin, Ohio, U.S.A.
Author: Dillon Worley
Publisher:
Total Pages: 140
Release: 2019
Genre:
ISBN:
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Being more extensive than the Marcellus Play, the Utica Play covers from New York state in the north to northeastern Kentucky and Tennessee in the south. The Utica Play is a stacked play consisting of organic-rich mudstones from upper Ordovician units of Utica Shale, Point Pleasant, and the Logana member of the Lexington/Trenton Limestone. This study will focus on the pore structure and rock-fluid interaction and with relation to the rocks geochemical properties to assess the Utica Play. To achieve this research purpose, 7 core samples and 16 cuttings, with different maturities were collected from various wells, to study rocks from Utica Shale, Point Pleasant, and Lexington Limestone, as well as the Kope Formation which is immediately above the Utica Shale. The research investigated the nano-petrophysics by the means of mercury injection capillary pressure (MICP), helium porosity and permeability, low-pressure nitrogen gas physisorption, contact angle, and spontaneous imbibition. The geochemistry of rocks was analyzed by pyrolysis and total organic content (TOC) measurements, while mineralogy was determined by X-ray diffraction (XRD). MICP results indicate that clay-rich formations have more intra-clay, organic-matter, and intragranular pores (2.8-50 nm in pore throats), while the more carbonate-rich samples possess a more prevalent amount of intragranular and intergranular pores (~ 100 nm in pore throats). Mineralogically speaking, carbonate and clay have an inverse relationship, as clay increases carbonate decreases. Samples have a low connectivity for the hydrophilic pore network but high for the hydrophobic pore network. From pyrolysis, S1 shows a positive correlation with MICP porosity. However, the Utica Shale and Point Pleasant Formation show a negative correlation suggesting OM may play a negative role in porosity development. Carbonate is not a controlling factor but influences overall porosity. When compared to other unconventional reservoirs, the Utica Play shows similar traits of hardness, brittleness, organic richness, porosity and permeability as other successful unconventional plays. For the Utica Play, this study provides a better understanding of pore structure and how thermal maturity can reduce porosity in mature samples due to the infilling of bitumen and mineralogy, specifically carbonate, influence porosity. Our mineralogy, petrophysical, and geochemical results support the Point Pleasant Formation being the target of the Utica Play. The better sustain production rate of Well B compared to Well A could be due to the more favorable petrophysical and geochemical properties of the Point Pleasant Formation. Knowing the petrophysical and geochemical characteristics of the Utica Play could aid in well placement, well design, and hydraulic fracture design and optimization.

Nano-petrophysics of the Marcellus Formation in Pennsylvania, USA

Nano-petrophysics of the Marcellus Formation in Pennsylvania, USA
Author: Christina Marie Muñoz
Publisher:
Total Pages: 100
Release: 2019
Genre:
ISBN:
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Characterizing unconventional shale reservoirs consisting of nano-size pores and pore networks are complicated due to their complex geometric structure and restrictive fluid transport abilities. Technological advancements with the use of multiple laboratory techniques for unconventional shale characterization has played key roles in determining their petrophysical properties with greater understanding and accuracy. Successful assessment of reservoir properties can be achieved by the measurement of porosity, permeability, pore size distribution, total organic carbon content, mineralogy, thermal maturity, wettability, tortuosity, with an understanding of the dispositional environments. The Marcellus covers as much as six states and occurs as deep as 9000 feet below the surface indicating a large potential and storage capacity for natural gas. Despite the Marcellus being the top shale gas producer in the United States it's also characterized by low porosity and permeability resulting in low-yields with declining production rates in some wells. In efforts to increase production or higher-yielding well completions in the shale, a greater understanding of the reservoir's petrophysical properties are essential for evaluation. This study will focus on the evaluation of nano-petrophysical properties of the Marcellus and underlying Utica that will provide additional information to the behavior of unconventional shale formations of the Appalachian basin, Pennsylvania. A series of experimental methodologies will be performed on samples gathered from five wells and two outcrops of the Marcellus and Utica formations in Pennsylvania. Analyses to be performed on samples include vacuum saturation, wettability/contact angle, x-ray diffraction (XRD), geochemistry, liquid pycnometry, mercury injection capillary pressure (MICP), imbibition and vapor absorption, and well-log analyses. Observations are then used to determine pore geometry and connectivity, migration, and storage characteristics within the Marcellus and Utica formations in the Appalachian basin, Pennsylvania. This will contribute to a better understanding of reservoir properties leading to the enhancement of well stimulation and completion methodologies for increased fluid migration and potentially increased production.

Mineralogical and Facies Variations Within the Utica Shale, Ohio Using Visible Derivative Spectroscopy, Principal Component Analysis, and Multivariate Clustering

Mineralogical and Facies Variations Within the Utica Shale, Ohio Using Visible Derivative Spectroscopy, Principal Component Analysis, and Multivariate Clustering
Author: Julie M Bloxson (Bloxson)
Publisher:
Total Pages: 207
Release: 2017
Genre: Appalachian Basin
ISBN:
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The Ordovician Utica Shale is an extensive and important part of the Appalachian Basin subsurface, providing a source for Paleozoic hydrocarbon reservoirs, acting as an unconventional hydrocarbon reservoir, and of interest as an impermeable cap rock for carbon dioxide sequestration in Cambrian formations. The Utica Shale is mostly in the subsurface, with little outcrops in areas of interest, and those that do exist are typically within the Appalachian Mountains (New York). To observe changes in subsurface formations, a combination of core and well logging can provide an extensive look into the subsurface. Here we present a non-destructive core-logging technique to quickly assess mineralogy variations on the Ordovician Trenton/Lexington Limestone, Point Pleasant Formation, and Utica Shale in Ohio. These core logging results, along with several previously measured core mineralogy, were then correlated to well logging electrofacies to extrapolate mineralogy and rock type from a few location to across the state. These were then mapped to identify controls on deposition during the Upper Ordovician in Ohio. Although typically assumed that the only controls on deposition during this time period are the primarily the Appalachian, and to a lesser extent Michigan, Basins, Precambrian basement structures, such as the Waverly Arch, Utica Mountain Fault, and Harlem Fault, have influence on deposition and sediment mixing also. Finally, the Sebree Trough, which has previously been reported to stop in southwest Ohio, appears to have allowed for dark, calcite-poor shales to continue deposition towards northeast Ohio, as a possible trough-like feature extending off of the Sebree Trough. The Trenton/Lexington Limestones, Point Pleasant Formation, and Utica Shale are not homogenous rock types, deposited across the state, but rather variable in both facies and thickness.

Reservoir Characterization

Reservoir Characterization
Author: Larry Lake
Publisher: Elsevier
Total Pages: 680
Release: 2012-12-02
Genre: Technology & Engineering
ISBN: 0323143512
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Reservoir Characterization is a collection of papers presented at the Reservoir Characterization Technical Conference, held at the Westin Hotel-Galleria in Dallas on April 29-May 1, 1985. Conference held April 29-May 1, 1985, at the Westin Hotel—Galleria in Dallas. The conference was sponsored by the National Institute for Petroleum and Energy Research, Bartlesville, Oklahoma. Reservoir characterization is a process for quantitatively assigning reservoir properties, recognizing geologic information and uncertainties in spatial variability. This book contains 19 chapters, and begins with the geological characterization of sandstone reservoir, followed by the geological prediction of shale distribution within the Prudhoe Bay field. The subsequent chapters are devoted to determination of reservoir properties, such as porosity, mineral occurrence, and permeability variation estimation. The discussion then shifts to the utility of a Bayesian-type formalism to delineate qualitative ""soft"" information and expert interpretation of reservoir description data. This topic is followed by papers concerning reservoir simulation, parameter assignment, and method of calculation of wetting phase relative permeability. This text also deals with the role of discontinuous vertical flow barriers in reservoir engineering. The last chapters focus on the effect of reservoir heterogeneity on oil reservoir. Petroleum engineers, scientists, and researchers will find this book of great value.

Multicomponent-seismic Characterization of the Utica Shale

Multicomponent-seismic Characterization of the Utica Shale
Author: Ahmet Serkan Kabakci
Publisher:
Total Pages: 186
Release: 2015
Genre:
ISBN:
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Recent development of gas shales in North America yield worldwide interest in gas production from shale formations. The methodology used in this thesis was to demonstrate multicomponent seismic technology for the characterization of shale-gas systems. The study area covers the Utica Shale across the Appalachian Basin in Bradford County, Pennsylvania. Concepts documented in this thesis can be used for other shale-gas systems. Unlike most shale-gas system studies, S-wave modes were used in addition to P-wave data in this study to better characterize the Utica Shale. Fast S-converted shear (P-SV1) and slow S-converted-shear (P-SV2) volumes provide new seismic imaging options for shale-gas studies and enable expanded seismic attributes that can be used to characterize shale-gas systems.

Hydraulic Fracturing for Oil and Gas

Hydraulic Fracturing for Oil and Gas
Author: U.s. Environmental Protection Agency
Publisher: Createspace Independent Publishing Platform
Total Pages: 664
Release: 2017-06-09
Genre: Drinking water
ISBN: 9781547257638
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This final report provides a review and synthesis of available scientific information concerning the relationship between hydraulic fracturing activities and drinking water resources in the United States. The report is organized around activities in the hydraulic fracturing water cycle and their potential to impact drinking water resources. The stages include: (1) acquiring water to be used for hydraulic fracturing (Water Acquisition), (2) mixing the water with chemical additives to prepare hydraulic fracturing fluids (Chemical Mixing), (3) injecting the hydraulic fracturing fluids into the production well to create fractures in the targeted production zone (Well Injection), (4) collecting the wastewater that returns through the well after injection (Produced Water Handling), and (5) managing the wastewater via disposal or reuse methods (Wastewater Disposal and Reuse). EPA found scientific evidence that hydraulic fracturing activities can impact drinking water resources under some circumstances. The report identifies certain conditions under which impacts from hydraulic fracturing activities can be more frequent or severe.