Geochemical applications in petroleum systems analysis: new constraints and the power of integration

Lawson, Michael; Formolo, Michael J; Summa, Lori L.; Eiler, John M.

doi:10.1144/sp468.6

Cited by 11 publications

(3 citation statements)

References 74 publications

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“…As such, migration of a hydrocarbon phase through this rock‐unit will inevitably result in some hydrocarbon‐water exchange. Migration pathways can vary in their length‐scale from short, in the case of some unconventional systems with interbedded sandstones and source intervals (e.g., Bakken shale), to long, that is (many hundreds of kilometers; Lawson et al, ). These findings have profound implications for how and where fluids interact in hydrocarbon systems, and thus the volumetric ratios that are predicted using equilibrium solubility models.…”

Section: Discussionmentioning

confidence: 99%

Noble Gases in Deepwater Oils of the U.S. Gulf of Mexico

Barry

Lawson

Meurer

et al. 2018

Geochem Geophys Geosyst

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Hydrocarbon migration and emplacement processes remain underconstrained despite the vast potential economic value associated with oil and gas. Noble gases provide information about hydrocarbon generation, fluid migration pathways, reservoir conditions, and the relative volumes of oil versus water in the subsurface. Produced gas He‐Ne‐Ar‐Kr‐Xe data from two distinct oil fields in the Gulf of Mexico (Genesis and Hoover‐Diana) are used to calibrate a model that takes into account both water‐oil solubility exchange and subsequent gas cap formation. Reconstructed noble gas signatures in oils reflect simple (two‐phase) oil‐water exchange imparted during migration from the source rock to the trap, which are subsequently modified by gas cap formation at current reservoir conditions. Calculated, oil to water volume ratios ( normalVnormalonormalVnormalw) in Tertiary‐sourced oils from the Hoover‐Diana system are 2–3 times greater on average than those in the Jurassic sourced oils from the Genesis reservoirs. Higher normalVnormalonormalVnormalw in Hoover‐Diana versus Genesis can be interpreted in two ways: either (1) the Hoover reservoir interval has 2–3 times more oil than any of the individual Genesis reservoirs, which is consistent with independent estimates of oil in place for the respective reservoirs, or (2) Genesis oils have experienced longer migration pathways than Hoover‐Diana oils and thus have interacted with more water. The ability to determine a robust normalVnormalonormalVnormalw, despite gas cap formation and possible gas cap loss, is extremely powerful. For example, when volumetric hydrocarbon ratios are combined with independent estimates of hydrocarbon migration distance and/or formation fluid volumes, this technique has the potential to differentiate between large and small oil accumulations.

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Section: Discussionmentioning

confidence: 99%

Noble Gases in Deepwater Oils of the U.S. Gulf of Mexico

Barry

Lawson

Meurer

et al. 2018

Geochem Geophys Geosyst

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“…Basin and petroleum system modelling (BPSM) is an important and advanced research method for oil and gas reservoir simulations and evaluations. It is widely used for hydrocarbon generation and expulsion from source rocks (Albriki et al, 2021; Alipour et al, 2022; Lutz et al, 2021; Wang et al, 2023; Zeinalzadeh et al, 2015), pressure and temperature (P–T) evolution (Mohamed et al, 2016; Nguyen et al, 2016), fluid property simulation and formation process prediction (Ahmed et al, 2022; Baur & Katz, 2018; D'Ambrosio et al, 2021; Evenick, 2022; Feng et al, 2020; Kishankov et al, 2022; Kroeger et al, 2021, 2022), and exploration risk assessment in low‐medium maturity and low‐exploration target regions (Badejo et al, 2021; Lawson et al, 2018; Liu & Liu, 2023). Its simulation path from the source rock to the traps has the ability to avoid relying on bitumen observations from massive but limited borehole data, making it possible to reconstruct the PORs distribution in the historical period of present‐day high to over‐mature regions.…”

Section: Introductionmentioning

confidence: 99%

Reconstruction of palaeo‐oil reservoirs in the ultra‐deep and over‐mature Sinian Dengying Formation of the Central Sichuan Basin: Insights from basin and petroleum system modelling

Li,

Liu,

Song

et al. 2024

Geological Journal

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Ultra‐deep Sinian carbonate rocks are rich in natural gas, and the Deng‐4 Member of the Central Sichuan Basin has been shown to have an extremely high degree of thermal evolution. They are characterized by dry gas produced due to the thermal cracking of palaeo‐oil reservoirs (PORs). The distribution of PORs as materials for the formation of cracked gas reservoirs remains unclear. The complex multistage evolution process and limited drilling data make it challenging to precisely and systematically recover a range of PORs. Based on basin and petroleum system modelling (BPSM), the bottom‐up migration and accumulation method was used to investigate the distribution of PORs. Research shows that the PORs in the Sinian Deng‐4 Member were mainly formed in the Early–Middle Triassic under the mixed contribution of Cambrian and Sinian source rocks, and the coupling of palaeostructural and trap settings controlled its accumulation. Generally, the distribution of PORs can be divided into two categories: one is located at the core of the uplift zone and is controlled by structural‐stratigraphic composite traps, whereas the other is controlled by a series of lithologic traps formed in the slope area. Sensitivity analysis showed that the distribution patterns of the PORs were mostly related to the facies conditions (physical characteristics) of the reservoirs. The widely distributed PORs provide necessary and sufficient material conditions for the formation of cracked Sinian gas reservoirs in the Central Sichuan Basin, and the North Slope area has great potential for natural gas exploration in the future.

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“…And, because the approach to equilibrium may be time dependent, it is possible that site specific hydrogen isotope fractionation may serve as a kind of 'geospeedometer' for evaluating gas reservoir storage times. This kinetic property in the carbonate geothermometer has been shown to have significant value for constraining thermal histories of rock samples (e.g., Passey and Henkes, 2012;Shenton et al, 2015;Lawson et al, 2018;Mangenot et al, 2019;Ingalls, 2019). If such a property were demonstrated in propane, it would provide an opportunity to assess the thermal histories of fluids that migrate within sedimentary systems.…”

Section: Introductionmentioning

confidence: 99%

Position-specific distribution of hydrogen isotopes in natural propane: Effects of thermal cracking, equilibration and biodegradation

Xie

Ponton

Formolo

et al. 2020

Geochimica et Cosmochimica Acta

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This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.

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Geochemical applications in petroleum systems analysis: new constraints and the power of integration

Cited by 11 publications

References 74 publications

Noble Gases in Deepwater Oils of the U.S. Gulf of Mexico

Noble Gases in Deepwater Oils of the U.S. Gulf of Mexico

Reconstruction of palaeo‐oil reservoirs in the ultra‐deep and over‐mature Sinian Dengying Formation of the Central Sichuan Basin: Insights from basin and petroleum system modelling

Position-specific distribution of hydrogen isotopes in natural propane: Effects of thermal cracking, equilibration and biodegradation

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