Evolution of petrophysical properties of oil shales during high-temperature compaction tests: Implications for petroleum expulsion

Eseme, E.; Krooß, Bernhard M.; Littke, Ralf

doi:10.1016/j.marpetgeo.2011.11.005

Cited by 52 publications

(27 citation statements)

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“…Such effects are still poorly understood and up to now very few experimental data have been published for shales (e.g. Eseme et al, 2007Eseme et al, , 2012.…”

Section: Adsorption Capacity and Gas Content During Burial Historymentioning

confidence: 99%

Thermal evolution and shale gas potential estimation of the Wealden and Posidonia Shale in NW‐Germany and the Netherlands: a 3D basin modelling study

et al. 2015

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Sedimentary basins in NW-Germany and the Netherlands represent potential targets for shale gas exploration in Europe due to the presence of Cretaceous (Wealden) and Jurassic (Posidonia) marlstones/shales as well as various Carboniferous black shales. In order to assess the regional shale gas prospectivity of this area, a 3D high-resolution petroleum system model has been compiled and used to reconstruct the source-rock maturation based on calibrated burial and thermal histories. Different basal heat flow scenarios and accordingly, different high-resolution scenarios of erosional amount distribution were constructed, incorporating all major uplift events that affected the study area. The model delivers an independent 3D reappraisal of the tectonic and thermal history that controlled the differential geodynamic evolution and provides a high-resolution image of the maturity distribution and evolution throughout the study area and the different basins. Pressure, temperature and TOCdependent gas storage capacity and gas contents of the Posidonia Shale and Wealden were calculated based on experimentally derived Langmuir sorption parameters and newly compiled source-rock thickness maps indicating shale gas potential of the Lower Saxony Basin, southern Gifhorn Trough and West Netherlands Basin.

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“…Such effects are still poorly understood and up to now very few experimental data have been published for shales (e.g. Eseme et al, 2007Eseme et al, , 2012.…”

Section: Adsorption Capacity and Gas Content During Burial Historymentioning

confidence: 99%

Thermal evolution and shale gas potential estimation of the Wealden and Posidonia Shale in NW‐Germany and the Netherlands: a 3D basin modelling study

et al. 2015

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“…However, besides oil generation potential, oil generation quantity is also closely related to the thermal evolution degree of OM and the oil generation quantity of the Upper Member shale with very great oil generation potential may also be lower than that of the Lower Member shale when the thermal evolution degree is low. (b) The oil expulsion efficiencies of the different types of OM vary as follows: Type‐I kerogen > Type‐II 1 kerogen > Type‐II 2 kerogen > Type‐III kerogen (Eseme, Krooss, & Littke, ; Inan, Yalcin, & Mann, ; Sandvik, Young, & Curry, ; Stainforth, ). As previously discussed in Section , the OM type of the Upper Member shale is generally better than that of the Lower Member shale; therefore, it should have a higher oil expulsion efficiency, whereas in the case of shale oil generation quantities having little difference, the amount of residual oil in the Upper Member shale would be lower, resulting in lower oil‐bearing capacity in the shale, which may be the main reason for the oil‐bearing capacity of the Upper Member shale being significantly lower than that of the Lower Member shale.…”

Section: Resultsmentioning

confidence: 99%

“…However, for shale oil play, the shale featuring strong remaining hydrocarbons is an excellent source rock; hence, the shale featuring strong oil generation capacity and small oil expulsion efficiency is the most favourable for the formation and enrichment of shale oil. In general, the stronger the oil generation capacity, the greater the oil expulsion efficiency (Eseme et al, ; Inan et al, ; Sandvik et al, ; Stainforth, ). Hence, the oil‐bearing capacity of the Upper Member Shale is significantly lower than that of the Lower Member Shale under the context of the thermal maturity difference being small, even though the OM abundance and oil generation of the Upper Member Shale are overall higher than the Lower Member shale.…”

Section: Resultsmentioning

confidence: 99%

“…hence, the shale featuring strong oil generation capacity and small oil expulsion efficiency is the most favourable for the formation and enrichment of shale oil. In general, the stronger the oil generation capacity, the greater the oil expulsion efficiency (Eseme et al, 2012;Inan et al, 1998;Sandvik et al, 1992;Stainforth, 2009) Based on the above analyses, in the P2l Formation shale, the depth intervals of 3, 255-3,272, 3,282-3,298, and 3,317-3,334 of the Lower Member in the well Ji174 are ideally suited and have the greatest shale oil exploration potential of Jimusar Sag in Junggar Basin.…”

Section: Implications For Shale Oil Explorationmentioning

confidence: 95%

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Geochemical and geological characteristics of Permian Lucaogou Formation shale of the well Ji174, Jimusar Sag, Junggar Basin, China: Implications for shale oil exploration

Pang

Wang

et al. 2017

Geological Journal

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Abundant shale oil resources were recently found in the organic‐rich Permian Lucaogou (P2l) Formation shale, Jimusar Sag, Junggar Basin. Although some scholars have conducted some researches on the basic geochemical characteristics of the Lucaogou Formation shale, it is not enough to effectively guide the shale oil exploration in the area. This is because during the exploration process of shale oil, besides the basic geochemical characteristics of shale, its mineral composition, physical properties, and oil‐bearing characteristics are all very important evaluation parameters. To systematically evaluate the favourable shale oil exploration sections in the Lucaogou Formation, 265 pieces of shale cores were sampled from well Ji174 in this study. Besides the basic geochemical characteristics of the 265 pieces of cores, the mineralogical, petrophysical, and oil‐bearing characteristics were also analysed. Results show that the shale has abundant organic matter (average total organic carbon 3.51%, average petroleum generation potential 15.67 mg/g), dominated by Type II1 and Type II2 kerogen, and has entered the early‐mature to mature stage. The Upper Member of the Lucaogou Formation has relatively higher organic matter and organic matter type is relatively more oil prone compared to the Lower Member; however, organic matter thermal maturity is lower. The P2l Formation shale is characterized by high carbonate minerals and low clay minerals, and when considering mineralogical brittleness, both the Upper and Lower members are ideally fracturable in shale oil development. The P2l Formation shale has a wide porosity range (1.1–13.9%), and the Lower Member's porosity is slightly greater. The inversion of shale porosity in the P2l Formation is controlled by the differentiated mineral composition. The oil saturation index values of the Lower Member shale are significantly greater than the Upper Member shale. From the above, the Lower Member of the P2l Formation shale is ideally suited and has greater shale oil potential in the Jimusar Sag, Junggar Basin, especially in the depth intervals of 3,255–3,272, 3,282–3,298, and 3,317–3,334 m in the well Ji174.

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“…In the context of petroleum system analysis, a significant volume of research has been undertaken regarding gas/oil expulsion mechanisms from sources rocks during burial history (Tissot & Pellet, 1971;Appold & Nunn, 2002), secondary migration (Luo et al, 2008) and the capillary sealing capacity of caprocks overlying natural gas accumulations (Berg, 1975;Schowalter, 1979;Krooss, 1992;Schlömer and Kross, 2004;Li et al, 2005;Berne et al, 2010). Recently, more attention has been paid to investigations of the transport efficiency of shales in the context of oil/gas shale production (Bustin et al, 2008;Eseme et al, 2012;Amann-Hildenbrand et al, 2012;Ghanizadeh et al, 2013Ghanizadeh et al, , 2014. Analysis of the migration mechanisms within partly unlithified strata becomes important when explaining the origin of overpressure zones, sub-seafloor gas domes and gas seepages (Hovland & Judd, 1988;Boudreau, 2012).…”

mentioning

confidence: 99%

Gas Transfer Through Clay Barriers

Amann-Hildenbrand

Krooss

Harrington

et al. 2015

Natural and Engineered Clay Barriers

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Evolution of petrophysical properties of oil shales during high-temperature compaction tests: Implications for petroleum expulsion

Cited by 52 publications

References 40 publications

Thermal evolution and shale gas potential estimation of the Wealden and Posidonia Shale in NW‐Germany and the Netherlands: a 3D basin modelling study

Thermal evolution and shale gas potential estimation of the Wealden and Posidonia Shale in NW‐Germany and the Netherlands: a 3D basin modelling study

Geochemical and geological characteristics of Permian Lucaogou Formation shale of the well Ji174, Jimusar Sag, Junggar Basin, China: Implications for shale oil exploration

Gas Transfer Through Clay Barriers

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