The dead line for oil and gas and implication for fossil resource prediction

Pang, Xiongqi; Jia, Chengzao; Zhang, Kun; Li, Maowen; Wang, Youwei; Peng, Junwen; Li, Boyuan; Chen, Junqing

doi:10.5194/essd-12-577-2020

Cited by 45 publications

(6 citation statements)

References 37 publications

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Section: Numerical Model Geometry and Parametrizationsupporting

confidence: 53%

“…According to the active source rock depth limit (Pang et al, 2020), the basin's heat flow generally controls the maximum burial depth for source rocks to generate and expel hydrocarbons produced by thermal cracking of kerogen (Behar et al, 1997). Since 1.6 MaBP, the Beaufort MD Basin exhibits an approximate heat flow of 55 mW m -2 (Figure 5B) in agreement with the moderate-heat-flow (40-60 mW m -2 ) basin suggested by Pang et al (2020). It implies that the upper limit of hydrocarbon generation, migration and accumulation is below 2,500 mbgl, conforming to the assumption that the GH-forming thermogenic gases originated from the Taglu Sequence (Figure 2B).…”

Section: Numerical Model Geometry and Parametrizationmentioning

confidence: 99%

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Geologic controls on the genesis of the Arctic permafrost and sub-permafrost methane hydrate-bearing system in the Beaufort–Mackenzie Delta

Chabab

Spangenberg

et al. 2023

Front. Earth Sci.

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The Canadian Mackenzie Delta exhibits a high volume of proven sub-permafrost gas hydrates that naturally trap a significant amount of deep-sourced thermogenic methane (CH4) at the Mallik site. The present study aims to validate the proposed Arctic sub-permafrost gas hydrate formation mechanism, implying that CH4-rich fluids were vertically transported from deep overpressurized zones via geologic fault systems and formed the present-day observed GH deposit since the Late Pleistocene. Given this hypothesis, the coastal permafrost began to form since the early Pleistocene sea-level retreat, steadily increasing in thickness until 1 Million years (Ma) ago. Data from well logs and 2D seismic profiles were digitized to establish the first field-scale static geologic 3D model of the Mallik site, and to comprehensively study the genesis of the permafrost and its associated GH system. The implemented 3D model considers the spatially heterogeneously distributed hydraulic properties of the individual lithologies at the Mallik site. Simulations using a proven thermo-hydro-chemical numerical framework were employed to gain insights into the hydrogeologic role of the regional fault systems in view of the CH4-rich fluid migration and the geologic controls on the spatial extent of the sub-permafrost GH accumulations during the past 1 Ma. For >87% of the Mallik well sections, the predicted permafrost thickness deviates from the observations by less than 0.8%, which validates the general model implementation. The simulated ice-bearing permafrost and GH interval thicknesses as well as sub-permafrost temperature profiles are consistent with the respective field observations, confirming our introduced hypothesis. The spatial distribution of GHs is a result of the comprehensive interaction between various processes, including the source-gas generation rate, subsurface temperature, and the hydraulic properties of the structural geologic features. Overall, the good agreement between simulations and observations demonstrates that the present study provides a valid representation of the geologic controls driving the complex permafrost-GH system. The model’s applicability for the prediction of GH deposits in permafrost settings in terms of their thicknesses and saturations can provide relevant contributions to future GH exploration and exploitation.

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Section: Numerical Model Geometry and Parametrizationsupporting

confidence: 53%

Section: Numerical Model Geometry and Parametrizationmentioning

confidence: 99%

Geologic controls on the genesis of the Arctic permafrost and sub-permafrost methane hydrate-bearing system in the Beaufort–Mackenzie Delta

Chabab

Spangenberg

et al. 2023

Front. Earth Sci.

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“…During deep burial, δ 13 C org values of kerogen may increase by up to +1‰ due to generation of 13 C-depleted oil and gas (Clayton, 1991). The present kerogen maturity (R o ) of the lower Cambrian black shales from the Tadong2 Well is about 2.7% (Zhang et al, 2004), higher than the 'oil window' (R o : 0.7-1.3%), but still in the 'gas window' (R o : <3.5%) (Pang et al, 2020). As such, the present δ 13 C org values should be slightly heavier than those of the primary δ 13 C org values.…”

Section: Reliability Of Carbon Isotope Valuesmentioning

confidence: 99%

Carbon Isotope Stratigraphy of the Cambrian System in the Eastern Tarim Basin, China

Wang

Jin

Wang

et al. 2022

Acta Geologica Sinica (Eng)

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The ultra-deep Cambrian System in the Tarim Basin is an important field for petroleum exploration, while fine division of the Cambrian strata remains controversial. In recent years, carbon isotope stratigraphy of the Cambrian System has been established and widely used. Here, we report an integrated profile of carbonate and organic carbon isotopic values (δ 13 C carb and δ 13 C org ) from cuttings of the Tadong2 Well in the eastern Tarim Basin. Three carbon isotope anomalies of BACE, ROECE and SPICE were recognized on the δ 13 C carb profile. Three apogees and a nadir on the δ 13 C org profile and the onset of ROECE on the δ 13 C carb profile were suggested as boundaries of the present four series of the Cambrian System. Suggested boundaries are easily identifiable on the gamma logging profile and is consistent with the previous division scheme, based on biostratigraphic evidence in outcrop sections. Abnormal carbon cycle perturbations and organic carbon burials during the BACE and SPICE events might be related to the reduction and expansion of a huge dissolved organic carbon reservoir in the deep ocean of the ancient Tarim Basin.

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“…The Mallik NGH accumulation occurs below thick permafrost and overlays directly on a free gas field sourced from deep thermal genetic gas of the basin. A basin wide study in the Beaufort-Mackenzie Basin (BMB) based on petrophysical logs from 251 oil and gas exploration wells showed that, although the NGH occurs in 122 wells (50%), only 7 contain net thickness greater than 5 meters, accounting for < 3% of the total wells studied (Osadetz and Chen 2010).…”

Section: Volumetric Methods Principlementioning

confidence: 99%

Evaluation and re-understanding of the global natural gas hydrate resources

Pang

Chen

Jia³

et al. 2021

Pet. Sci.

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Natural gas hydrate (NGH) has been widely considered as an alternative to conventional oil and gas resources in the future energy resource supply since Trofimuk’s first resource assessment in 1973. At least 29 global estimates have been published from various studies so far, among which 24 estimates are greater than the total conventional gas resources. If drawn in chronological order, the 29 historical resource estimates show a clear downward trend, reflecting the changes in our perception with respect to its resource potential with increasing our knowledge on the NGH with time. A time series of the 29 estimates was used to establish a statistical model for predict the future trend. The model produces an expected resource value of 41.46 × 1012 m3 at the year of 2050. The statistical trend projected future gas hydrate resource is only about 10% of total natural gas resource in conventional reservoir, consistent with estimates of global technically recoverable resources (TRR) in gas hydrate from Monte Carlo technique based on volumetric and material balance approaches. Considering the technical challenges and high cost in commercial production and the lack of competitive advantages compared with rapid growing unconventional and renewable resources, only those on the very top of the gas hydrate resource pyramid will be added to future energy supply. It is unlikely that the NGH will be the major energy source in the future.

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The dead line for oil and gas and implication for fossil resource prediction

Cited by 45 publications

References 37 publications

Geologic controls on the genesis of the Arctic permafrost and sub-permafrost methane hydrate-bearing system in the Beaufort–Mackenzie Delta

Geologic controls on the genesis of the Arctic permafrost and sub-permafrost methane hydrate-bearing system in the Beaufort–Mackenzie Delta

Carbon Isotope Stratigraphy of the Cambrian System in the Eastern Tarim Basin, China

Evaluation and re-understanding of the global natural gas hydrate resources

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