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2. Geochemical and isotopic approach to maturity/source/mixing estimations for natural gas and associated condensates in the Thrace Basin, NW Turkey

Author

R. Paul Philp, Muzaffer Siyako, Chris Clayton, Hasan Emiroğlu, and Kadir Gürgey

Subjects
Turkey, Geochemistry, Mineralogy, Source, Methane, condensate, chemistry.chemical_compound, Isotopes, source rock, Geochemistry and Petrology, Kerogen, Environmental Chemistry, Thrace Basin, geochemistry, Maturity (geology), Eastern Hemisphere, Carbon isotope, GCIRMS, World, Carbon isotopes, Bacteriology, Natural gas, Pollution, Oil, Correlation, Natural gas field, Europe, chemistry, Condensates, Isotopes of carbon, thermal maturity, Catchments, Crack initiation, Eurasia, Sedimentary rock, Reservoirs (water), Sedimentation, Oil shale, Paleogene, Geology
Abstract

The Tertiary Thrace Basin located in NW Turkey comprises 9 km of clastic-sedimentary column ranging in age from Early Eocene to Recent in age. Fifteen natural gas and 10 associated condensate samples collected from the 11 different gas fields along the NW-SE extending zone of the northern portion of the basin were evaluated on the basis of their chemical and individual C isotopic compositions. For the purpose of the study, the genesis of CH 4, thermogenic C2+ gases, and associated condensates were evaluated separately. Methane appears to have 3 origins: Group-1 CH4 is bacteriogenic (Calculated ?13CC1-C = -61.48‰; Silivri Field) and found in Oligocene reservoirs and mixed with the thermogenic Group-2 CH4. They probably formed in the Upper Oligocene coal and shales deposited in a marshy-swamp environment of fluvio-deltaic settings. Group-2 (?13CC1-C = -35.80‰; Hamitabat Field) and Group-3 (?13C 1-C = -49.10‰; Degirmenköy Field) methanes are thermogenic and share the same origin with the Group-2 and Group-3 C 2+ gases. The Group-2 C2+ gases include 63% of the gas fields. They are produced from both Eocene (overwhelmingly) and Oligocene reservoirs. These gases were almost certainly generated from isotopically heavy terrestrial kerogen (?13C = -21‰) present in the Eocene deltaic Hamitabat shales. The Group-3 C2+ gases, produced from one field, were generated from isotopically light marine kerogen (?13C = -29‰). Lower Oligoce ne Mezardere shales deposited in pro-deltaic settings are believed to be the source of these gases. The bulk and individual n-alkane isotopic relationships between the rock extracts, gases, condensates and oils from the basin differentiated two Groups of condensates, which can be genetically linked to the Group-2 and -3 thermogenic C2+ gases. However, it is crucial to note that condensates do not necessarily correlate to their associated gases. Maturity assessments on the Group-1 and -2 thermogenic gases based on their estimated initial kerogen isotope values (?13C = -21‰; -29‰) and on the biomarkers present in the associated condensates reveal that all the hydrocarbons including gases, condensates and oils are the products of primary cracking at the early mature st age (Req = 0.55-0.81%). It is demonstrated that the open-system source conditions required for such an early-mature hydrocarbon expulsion exist and are supported by fault systems of the basin. © 2005 Elsevier Ltd. All rights reserved.

Published
2005

3. Petroleum Geochemistry: Concepts, Applications, and Results

Author

Laurence Mansuy, R. Paul Philp, University of Oklahoma (OU), and Institut National Polytechnique de Lorraine (INPL)

Subjects
business.industry, 020209 energy, General Chemical Engineering, Earth science, Fossil fuel, Energy Engineering and Power Technology, Mineralogy, 02 engineering and technology, Fuel Technology, 020401 chemical engineering, Source rock, [SDU.STU.GC]Sciences of the Universe [physics]/Earth Sciences/Geochemistry, Organic geochemistry, [SDE]Environmental Sciences, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, 0204 chemical engineering, business, Petroleum geochemistry, ComputingMilieux_MISCELLANEOUS
Abstract

Petroleum geochemistry has played an important role in many areas of exploration and production for fossil fuels. Many of the more recent developments can be seen to have developed in parallel with developments in analytical chemistry such as gas chromatography and gas chromatography−mass spectrometry. For the past two decades such analytical techniques have been used to search for trace amounts of compounds known as biomarkers present in oils and source rock extracts which can be used to provide valuable information on the origin and history of the oil. In the past two or three years much more effort has been placed on the development and utilization of such techniques as an aid to solving reservoir and production problems. In this paper it is proposed to provide an overview of major developments that have occurred in a number of areas of geochemistry in recent years. This will include developments in reservoir geochemistry such as the use of high-resolution gas chromatography for reservoir continuity st...

Published
1997
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4. The emergence of stable isotopes in environmental and forensic geochemistry studies: a review

Author

R. Paul Philp

Subjects
Chlorinated solvents, Stable isotope ratio, Environmental remediation, Chemistry, Environmental chemistry, Isotope geochemistry, Isotopes of chlorine, Environmental Chemistry, BTEX
Abstract

In the past decade, environmental forensics has emerged as a discipline directed toward determining parties liable for causing spills of contaminants into the environment. Such investigations, while geared toward determining the guilty parties in order to recover costs of the cleanup and remediation, require various questions to be addressed. These include determination of the nature of the product; Where did it come from?; Extent of weathering, if any; How long has it been there?; and Is it degrading naturally? Traditionally, these studies have been addressed through utilization of techniques such as gas chromatography (GC) and gas chromatography–mass spectrometry (GCMS). However, in recent years, stable isotopes, primarily determined through the use of combined gas chromatography–isotope ratio mass spectrometry (GCIRMS), have emerged as an equally important tool in environmental forensics. For relatively low molecular, volatile compounds such as MTBE, BTEX, or chlorinated solvents, the isotopes, primarily carbon and hydrogen, have been used extensively for evaluating the onset of natural attenuation. For larger molecules such as PCBs or PAHs, in which the effects of biodegradation on the isotope composition of these molecules is minimal, the isotopic fingerprints of the individual compounds can be used for correlation purposes. In this paper, a brief introduction to isotope geochemistry will be given, followed by a review of applications of stable isotopes to a variety of environmental problems. While the review may not necessarily be exhaustive, it will provide a comprehensive overview of areas where isotopes have been used and potential applications for the future. Most of the review is concerned with carbon and hydrogen isotopes, although a brief overview of the emerging area of chlorine isotopes will also be discussed.

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5. Geochemistry of Sulfur in Fossil Fuels

Author

WILSON L. ORR, CURT M. WHITE, Jaap S. Sinninghe Damsté, C.-L. Chou, B. Manowitz, F. W. Lipfert, Robert T. LaLonde, O. P. Strausz, E. M. Lown, J. D. Payzant, Phillip M. Fedorak, Michele L. Tuttle, Cynthia A. Rice, Martin B. Goldhaber, Jürgen Rullkötter, Ralf Littke, Rainer G. Schaefer, F. Kenig, A. Y. Huc, A. M. Bailey, J. F. Sherrill, J. H. Blackson, E. C. Kosters, T. S. White, J. L. Morrison, L. R. Kump, Graham N. George, Martin L. Gorbaty, Simon R. Kelemen, J. T. Riley, G. M. Ruba, C. C. Lee, Leon M. Stock, Ryszard Wolny, Randall E. Winans, Paul H. Neill, L. J. Douglas, R. R. Anderson, C. E. Schmidt, R. J. Gray, R. J. Torres-Ordoñez, W. H. Calkins, M. T. Klein, Stephen R. Palmer, Edwin J. Hippo, Michael A. Kruge, John C. Crelling, Elizabeth Ge, Charles Wert, Allen J. Bakel, R. Paul Philp, A. Galvez-Sinibaldi, Jean-Paul Boudou, T. M. Peakman, A. C. Kock-van Dalen, Jan W. de Leeuw, Mathieu E. L. Kohnen, W. Irene C. Rijpstra, Timothy I. Eglinton, Steve R. Larter, Richard L. Patience, J. W. Smith, R. Phillips, Erdem F. Idiz, Eli Tannenbaum, Isaac R. K, WILSON L. ORR, CURT M. WHITE, Jaap S. Sinninghe Damsté, C.-L. Chou, B. Manowitz, F. W. Lipfert, Robert T. LaLonde, O. P. Strausz, E. M. Lown, J. D. Payzant, Phillip M. Fedorak, Michele L. Tuttle, Cynthia A. Rice, Martin B. Goldhaber, Jürgen Rullkötter, Ralf Littke, Rainer G. Schaefer, F. Kenig, A. Y. Huc, A. M. Bailey, J. F. Sherrill, J. H. Blackson, E. C. Kosters, T. S. White, J. L. Morrison, L. R. Kump, Graham N. George, Martin L. Gorbaty, Simon R. Kelemen, J. T. Riley, G. M. Ruba, C. C. Lee, Leon M. Stock, Ryszard Wolny, Randall E. Winans, Paul H. Neill, L. J. Douglas, R. R. Anderson, C. E. Schmidt, R. J. Gray, R. J. Torres-Ordoñez, W. H. Calkins, M. T. Klein, Stephen R. Palmer, Edwin J. Hippo, Michael A. Kruge, John C. Crelling, Elizabeth Ge, Charles Wert, Allen J. Bakel, R. Paul Philp, A. Galvez-Sinibaldi, Jean-Paul Boudou, T. M. Peakman, A. C. Kock-van Dalen, Jan W. de Leeuw, Mathieu E. L. Kohnen, W. Irene C. Rijpstra, Timothy I. Eglinton, Steve R. Larter, Richard L. Patience, J. W. Smith, R. Phillips, Erdem F. Idiz, Eli Tannenbaum, and Isaac R. K

Subjects
Petroleum--Sulfur content--Congresses, Coal--Sulfur content--Congresses, Geochemistry--Congresses
Published
1990

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