Journal
FRONTIERS IN EARTH SCIENCE
Volume 9, Issue -, Pages -Publisher
FRONTIERS MEDIA SA
DOI: 10.3389/feart.2021.786667
Keywords
marine-terrestrial transitional shale; pyrolysis experiment; oil generation and expulsion; organic sources; maturity
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Shale reservoirs are characterized by self-generation and self-accumulation, and the oil generation and expulsion evolutions of marine-terrestrial transitional shales differ significantly from marine and lacustrine shales. The main stages of oil expulsion in marine-terrestrial transitional shales are later than those of oil generation, with compositions dominated by heavy components. The organic sources of terrigenous higher organisms play a crucial role in determining the oil generation and expulsion evolutions of these shales.
Shale reservoirs are characterized by self-generation and self-accumulation, and the oil generation and expulsion evolution model of organic-rich shales is one of important factors that obviously influence the enrichment and accumulation of shale oil and gas resources. At present, however, relevant studies on marine-terrestrial transitional shales are inadequate. In this study, a pyrolysis experiment was performed on water-saturated marine-terrestrial transitional shale plunger samples with type IIb kerogen to simulate the evolutions of oil generation and expulsion. The results indicate that marine-terrestrial transitional shales have wider maturity ranges of oil generation and expulsion than marine and lacustrine shales, and the main stages of oil expulsion are later than those of oil generation, with corresponding R-o values of 0.85%-1.15% and 0.70%-0.95%, respectively. Although the oil generation and expulsion process induced a fractionation in compositions between the expelled and retained oils, both the expelled and retained oils of marine-terrestrial transitional shales are dominated by heavy compositions (resins and asphaltenes), which significantly differs from those of marine and lacustrine shales. The kerogen of marine-terrestrial transitional shales initially depolymerized to transitional asphaltenes, which further cracked into hydrocarbons, and the weak swelling effects of the kerogen promoted oil expulsions. The oil generation and expulsion evolutions of these shales are largely determined by their organic sources of terrigenous higher organisms. This study provides a preliminary theoretical basis to reveal the enrichment mechanism of marine-terrestrial transitional shale oil and gas resources.
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