Abstract
To the accurate reconstruction of the hydrocarbon generation history in the Dongying Depression, Bohai Bay Basin, East China, core samples of the Eocene Shahejie Formation from 3 shale oil boreholes were analyzed using organic petrology and organic geochemistry methods. The shales are enriched in organic matter with good to excellent hydrocarbon generation potential. The maturity indicated by measured vitrinite reflectance (%Ro) falls in the range of 0.5–0.9% and increases with burial depth in each well. Changes in biomarker and aromatic hydrocarbon isomer distributions and biomarker concentrations are also unequivocally correlated with the thermal maturity of the source rocks. Maturity/depth relationships for hopanes, steranes, and aromatic hydrocarbons, constructed from core data indicate different well locations, have different thermal regimes. A systematic variability of maturity with geographical position along the depression has been illustrated, which is a dependence on the distance to the Tanlu Fault. Higher thermal gradient at the southern side of the Dongying Depression results in the same maturity level at shallower depth compared to the northern side. The significant regional thermal regime change from south to north in the Dongying Depression may exert an important impact on the timing of hydrocarbon maturation and expulsion at different locations. Different exploration strategies should be employed accordingly.
Highlights
Determining the thermal maturity of source rocks is crucial for the prediction of petroleum generation time and the exploration potential in a sedimentary basin
Pyrolysis results indicate that the Shahejie Formation has excellent organic matter quality, quantity, and hydrocarbon generation potential
The total organic carbon (TOC) contents vary in the range of 1.44–7.66 wt% with an average value of 3.62 wt%, indicating high petroleum generation potential
Summary
Determining the thermal maturity of source rocks is crucial for the prediction of petroleum generation time and the exploration potential in a sedimentary basin. Various petrological and geochemical methods can be applied for thermal history reconstruction, which include vitrinite reflectance (%Ro), Rock-Eval, Tmax, kerogen H/C ratio, degree of biomarker isomerization, homogenization temperature in fluid inclusions, apatite fission track analysis, and many other maturity indicators [1,2,3,4,5]. Applied petroleum system modeling techniques largely rely on the reaction kinetics of kerogens and thermal maturity of source rocks to predict the timing of oil and gas generation and identify hydrocarbon production targets [6,7,8]. Tmax of the Rock-Eval pyrolysis offers the easiest way to assess source rock maturity levels [10]; Tmax suppression may occur in some liptinite enriched kerogens [11, 12]
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