Integrated 3D forward stratigraphic and petroleum system modeling of the Levant Basin, Eastern Mediterranean

Barabasch, Jessica; Ducros, Mathieu; Hawie, Nicolas; Daher, Samer Bou; Nader, Fadi H.; Littke, Ralf

doi:10.1111/bre.12318

Cited by 20 publications

(20 citation statements)

References 66 publications

(166 reference statements)

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“…Although we cannot conclusively show the past existence of overpressure in the distal Lebanese offshore, it most likely occurred by analogy with the southern Levant Basin (Bertoni et al, 2017). Our hypothesis also agrees with models for the regional petroleum system, which postulate up-dip hydrocarbon migration eastwards from biogenic and thermogenic source rocks located towards the deeper basin (Barabasch et al, 2018;Ghalayini et al, 2018;Nader et al, 2018). Besides promoting fluid migration, basin margin uplift may have also reduced the water column along the margin, inducing gas exsolution from the hydrocarbons already trapped in the anticlines, thus increasing overpressure by buoyancy (e.g.…”

Section: Overpressure Generation and Hydrofracturingsupporting

confidence: 86%

“…However, direct hydrocarbon indicators and stratigraphic correlation with nearby areas point to a potentially prolific basin. Many possible source rocks spanning from the Permian/Triassic to the Miocene are identified in various areas of the basin (Barabasch et al, 2018;Ghalayini et al, 2018;Marlow et al, 2011). Thermogenic hydrocarbon generation has been active since the Late Cretaceous in the deeper basin and Latakia Ridge (Bou Daher et al, 2016), whereas biogenic methane generation started in the Miocene across the Lebanese offshore.…”

Section: Geological Settingmentioning

confidence: 99%

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Leaky salt: pipe trails record the history of cross-evaporite fluid escape in the northern Levant Basin, Eastern Mediterranean

Oppo¹,

Evans²,

Jackson³

et al. 2021

Preprint

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Hydrocarbon escape systems can be regionally active on multi-million-year timescales. However, reconstructing the timing and evolution of repeated escape events can be challenging because their expression may overlap in time and space. In the northern Levant Basin, eastern Mediterranean, distinct fluid escape episodes from common leakage points formed discrete, cross-evaporite fluid escape pipes, which are preserved in the stratigraphic record due to the coeval Messinian salt tectonics.The pipes consistently originate at the crest of prominent sub-salt anticlines, where thinning and hydrofracturing of overlying salt permitted focused fluid flow. Sequential pipes are arranged in several kilometers-long trails that were progressively deformed due to basinward gravity-gliding of salt and its overburden. The correlation of the oldest pipes within 12 trails suggests that margin-wide fluid escape started in the Late Pliocene/Early Pleistocene, coincident with a major phase of uplift of the Levant margin. We interpret that the consequent transfer of overpressure from the deeper basin areas triggered seal failure and cross-evaporite fluid flow. We infer that other triggers, mainly associated with the Messinian Salinity Crisis and compressive tectonics, played a secondary role in the northern Levant Basin. Further phases of fluid escape are unique to each anticline and, despite a common initial cause, long-term fluid escape proceeded independently according to structure-specific characteristics, such as the local dynamics of fluid migration and anticline geometry.Whereas cross-evaporite fluid escape in the southern Levant Basin is mainly attributed to the Messinian Salinity Crisis and compaction disequilibrium, we argue that these mechanisms do not apply to the northern Levant Basin; here, fluid escape was mainly driven by the tectonic evolution of the margin. Within this context, our study shows that the causes of cross-evaporite fluid escape can vary over time, act in synergy, and have different impacts in different areas of large salt basins.

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Section: Overpressure Generation and Hydrofracturingsupporting

confidence: 86%

Section: Geological Settingmentioning

confidence: 99%

Leaky salt: pipe trails record the history of cross-evaporite fluid escape in the northern Levant Basin, Eastern Mediterranean

Oppo¹,

Evans²,

Jackson³

et al. 2021

Preprint

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“…This is ca. 15-20 Ma earlier than proposed by Barabasch et al (2019) or Bou Daher et al 2016, who, however, did not distinguish between the lower and upper boundary of these source rocks. Source rocks falling into this zone of maturation have converted 50% of its initial kerogen between 20 and 15 Ma, and almost 100% at present day (Figure 15g,h, location 1).…”

Section: Upper Cretaceous Source Rocksmentioning

confidence: 54%

“…Consequently, the sediment supply coming from the Nile had to be increased with each deactivated source in order to still fill the complete basin. Sediment supply as well as fluvial discharge were mainly adopted from Hawie et al (2015) and Barabasch et al, (2019).…”

Section: Oligocene To Miocenementioning

confidence: 99%

Characterization of Late Cretaceous to Miocene source rocks in the Eastern Mediterranean Sea: An integrated numerical approach of stratigraphic forward modelling and petroleum system modelling

et al. 2020

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Stratigraphic forward modelling was used to simulate the deposition of Upper Cretaceous, Eocene and Oligo‐Miocene source rocks in the Eastern Mediterranean Sea and, thus, obtain a process‐based 3D prediction of the quantity and quality distribution of organic matter (OM) in the respective intervals. Upper Cretaceous and Eocene models support the idea of an upwelling‐related source rock formation along the Levant Margin and the Eratosthenes Seamount (ESM). Along the margin, source rock facies form a narrow band of 50 km parallel to the palaeo shelf break, with high total organic carbon (TOC) contents of about 1% to 11%, and HI values of 300–500 mg HC/g TOC. On top of the ESM, TOC contents are mainly between 0.5% and 3% and HI values between 150 and 250 mg HC/g TOC. At both locations, TOC and HI values decrease rapidly towards the deeper parts of the basin. In the Oligo‐Miocene intervals, terrestrial OM makes up the highest contribution to the TOC content, as marine organic matter (OM) is diluted by high‐sedimentation rates. In general, TOC contents are low (<1%), but are distributed relatively homogenously throughout the whole basin, creating poor quality, but very thick source rock intervals of 1–2 km of cumulative thickness. The incorporation of these source rock models into a classic petroleum system model could identify several zones of thermal maturation in the respective source rock intervals. Upper Cretaceous source rocks started petroleum generation in the late Palaeocene/early Eocene with peak generation between 20 and 15 Ma ca. 50 km offshore northern Lebanon. Southeast of the ESM, generation started in the early Eocene with peak generation between 18 and 15 Ma. Eocene source rocks started HC generation ca. 25 Ma ago between 50 and 100 km southeast of the ESM and reached the oil to wet gas window at present day. However, until today they have converted less than 20% of their initial kerogen. Although the Miocene source rocks are mostly immature, Oligocene source rocks lie within the oil window in the southern Levant Basin and reached the onset of the wet gas window in the northern Levant Basin. However, only 10%–20% of their initial kerogen have been transformed to date.

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“…Forward stratigraphic modeling can be applied to predict the location and heterogeneity of depositional systems and petroleum reservoirs (Miller et al, 2008), as well as the depositional response to controlling factors (Piper and Normark, 2001). For example, in an exploration scenario with lowresolution seismic-reflection data (generally two-dimensional, 2-D, profiles with frequencies of 5-20 Hz; Normark et al, 1993;Prather et al, 2012) and no lithologic control from well penetrations, seismic-stratigraphic interpretation and structural restoration can be applied to create a paleotopographic surface for modeling the location, size, shape, and sub-seismic heterogeneity and stacking of deposits (Groenenberg et al, 2010;Aas et al, 2014;Deville et al, 2015;Hawie et al, 2017;Barabasch et al, 2019). Commonly used geostatistical methods in reservoir modeling use semivariograms, geometric parameters, and/or training images to reproduce spatial statistics from available seismic-reflection and well data (Pyrcz and Deutsch, 2014;Pyrcz et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Grain-Size and Discharge Controls on Submarine-Fan Depositional Patterns From Forward Stratigraphic Models

2019

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Submarine fans are important components of continental margins; they contain a stratigraphic record of environmental changes and host large accumulations of oil and gas. The grain size and volume of sediment supply to fans is thought to control the heterogeneity of deep-water deposits; predicting spatial variability of sandy and muddy deposits is an important applied challenge in the characterization of fans. Here, we use DionisosFlow stratigraphic-forward models to evaluate the sensitivity of submarine-fan deposition to a range of grain sizes, with corresponding diffusion coefficients ranging from 10 to 100 km 2 /kyr for coarse sand to silt/clay, and discharges. In general, finer grains are transported farther in our models because they have larger diffusion coefficients. Coarser grains typical of a sand-rich fan tend to pile up and compensationally stack at the mouth of a proximal feeder channel. Increasing sediment-gravity-flow discharge resulted in a thicker depositional system; however, relatively coarse sediment piled up at the mouth of the feeder channel, which created a slope that promoted basinward sediment transport. Our modeling results can be applied to predict the overall geometry, stacking, and grain-size distribution of submarine fans. Improved understanding of grain-size and discharge controls also informs interpretation of the stratigraphic record of submarine fans. For example, outcrop observations of heterogeneity and compensational stacking of depocenters can be related to changing boundary conditions, namely changes in the caliber and overall supply of sediment delivery to deep-water basin margins.

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Integrated 3D forward stratigraphic and petroleum system modeling of the Levant Basin, Eastern Mediterranean

Cited by 20 publications

References 66 publications

Leaky salt: pipe trails record the history of cross-evaporite fluid escape in the northern Levant Basin, Eastern Mediterranean

Leaky salt: pipe trails record the history of cross-evaporite fluid escape in the northern Levant Basin, Eastern Mediterranean

Characterization of Late Cretaceous to Miocene source rocks in the Eastern Mediterranean Sea: An integrated numerical approach of stratigraphic forward modelling and petroleum system modelling

Grain-Size and Discharge Controls on Submarine-Fan Depositional Patterns From Forward Stratigraphic Models

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