Investigations on the shale oil and gas potential of Westphalian mudstone successions in the Campine Basin, NE Belgium (well KB174): Palaeoenvironmental and palaeogeographical controls

Vandewijngaerde, Wim; Piessens, Kris; Dusar, Michiel; Bertier, Pieter; Krooß, Bernhard M.; Littke, Ralf; Swennen, Rudy

doi:10.20341/gb.2016.009

Cited by 6 publications

(3 citation statements)

References 32 publications

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“…Gas storage in unconventional shale reservoirs is a complex multiparameter problem. Studies to date identify organic matter characteristics (total organic carbon (TOC) content, thermal maturation, and kerogen type), mineralogy, pore system, moisture, pressure, and temperature as important parameters in assessment of gas sorption capacity of shales. − Organic matter in shales has been considered as the first contributor to gas sorption capacity of shales. Previous studies have reported the positive correlation between TOC content and methane sorption on black shales of North America and Europe. , Thermal maturity of organic matter has a positive effect on the methane sorption capacity of shales, and this is ascribed to the increase in the organic micropores and/or change in chemistry characteristics of organic matter during thermal maturation. , When it comes to the type of organic matter of shales, sorption capacity on TOC basis was reported to increase in order: type I < type II < type III, and this was attributed to the larger micropore surface area of humic kerogen compared to other maceral composition when the organic matter is highly mature and the increasing kerogen aromaticity of organic matter in the progression from type I to type III kerogen. − In addition to organic matter, pores of inorganic constituents (clay minerals) accommodate additional sorbed gas due to their developed internal surface area, and contribute appreciable amounts of gas sorption in clay-rich shales under dry condition. ,,, …”

Section: Introductionmentioning

confidence: 99%

High-Pressure Methane Sorption on Dry and Moisture-Equilibrated Shales

et al. 2016

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High-pressure methane sorption isotherms were collected on selected Paleozoic shales from the Sichuan Basin. Excess sorption measurements were performed on shales with varied water content (dry, moisture equilibrated at 33%, 53%, 75%, and 97% relative humidities) at 39 °C and up to 25 MPa. Water uptake isotherms were collected at 24 °C and parametrized by the Guggenheim–Anderson–de Boer (GAB) model. The effect of organic richness, mineral compositions, and pore structure characteristics on water uptake and methane sorption behavior has been investigated. The mechanism responsible for the decrease in methane sorption capacity of moisture-equilibrated shales is discussed. Water uptake of shales is primarily controlled by clay minerals, and shows a positive correlation with clay mineral content. Water sorption isotherms of shales can be approximately expressed as the sum of the isotherms of individual clay minerals on a mass-fraction base. Methane sorption capacity of these shales is controlled by TOC content. The maximum Langmuir sorption capacity of shales under both dry and 97% RH conditions correlates positively with TOC content. Compared to dry conditions, methane sorption capacity of shales moisture-equilibrated at 97% RH is reduced by 44% to 63%. The experimental results indicate a stepwise decline in methane sorption with increasing water content. Evolution of sorption capacity as a function of water content can be divided into three stages: (1) initial decline stage where the decrease of methane sorption capacity is mainly due to competitive sorption of methane and water on hydrophilic clay minerals; (2) steep decline stage where clusters of water molecules block pore space and reduce the sorption capacity significantly; and (3) slow decline stage, where a contiguous water phase successively fills the macropores and slightly reduces methane sorption by volume displacement.

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Section: Introductionmentioning

confidence: 99%

High-Pressure Methane Sorption on Dry and Moisture-Equilibrated Shales

et al. 2016

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“…Concerns about the accurate evaluation of gas content and diffusion kinetics have led to many experimental studies about gas sorption on shales. Significant progress has been achieved in the controls on sorption capacity of shales. − However, data on high-temperature high-pressure sorption isotherms of shales are still scare. In particular, the burial depth of the Paleozoic shales in the Upper Yangtze region of China is mostly in a range of 2000–4000 m, − which indicates that the temperature and pressure of shale reservoirs are in the range of 60–120 °C and 20–40 MPa, assuming the hydrostatic pressure and normal geothermal gradients (0.01 MPa/m, 0.03 °C/m).…”

Section: Introductionmentioning

confidence: 99%

Supercritical Methane Sorption on Organic-Rich Shales over a Wide Temperature Range

Yang

Xie

et al. 2017

Energy Fuels

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Methane sorption on organic-rich shales over wide temperature and pressure ranges (30–120 °C, up to 25 MPa) is analyzed by the pore filling/potential theory. The supercritical Dubinin–Astakhov (SDA) sorption model using a density term instead of the pseudosaturation vapor term is extended to methane sorption isotherms of shales with high accuracy. A modified adsorption potential approach is suggested to analyze the temperature dependence of supercritical methane sorption on shales. The temperature-invariant characteristic curves are obtained using the modified adsorption potential approach. A characteristic curve equation derived from the SDA model is provided to predict sorption isotherms at other temperatures using one isotherm. The physical meaning of the characteristic curve has been discussed, and it comprehensively reflects the available pore space for methane sorption and the affinity between methane molecules and organic matter. According to methane characteristic curves of shales and clay minerals, shales in the gas window show higher affinity than shales in the oil window and clay minerals, though the clay minerals may provide comparable adsorbed volume. The adsorption characteristic energy shows a parabola-like shape with a minimum of approximately R eq = 1.1%, which is related to the evolution of the porosity of the shales. This study advanced the fundamental understanding of the dynamic process of methane sorption on shales.

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“…This led to a net export of dissolution products such as silica, that was redistributed to other surrounding sandstones, such as the coarser grained bleached sandstones that acted as a sink, since this mesogenetic AQ cement type is more common in these sandstones. As stated above, based on mass balance calculations, Muchez et al (1992) calculated that the released amount of fluids with dissolved organic acids was more than enough for explaining the observed iron-reduction, even without taking the intercalated organic Westphalian shales into account (see also Vandewijngaerde et al, 2016). Part or all of the released ferric iron was incorporated into the mesogenetic zoned ankerite and siderite, indicating that the system with regard to Fe acted as a (partly) closed system.…”

Section: Open Versus Closed System Diagenesismentioning

confidence: 96%

Reservoir characteristics and diagenesis of the Buntsandstein sandstones in the Campine Basin (NE Belgium)

Bertier¹,

Swennen²,

KEMPS³

et al. 2022

Geol. Belg.

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The red beds of the Buntsandstein (Early Triassic) in the Campine Basin (NE Belgium) display porosities between 5.3–20.2% (average 13.7%) and permeabilities varying between 0.02–296.4 mD (average 38.7 mD). Knowledge of their reservoir controlling properties, which today are missing, is important in view of potential geological storage of CO2 or natural gas and geothermal reservoir potential within these sandstones. Therefore the effects of diagenesis were assessed based on petrography, stable isotope analyses, fluid inclusion microthermometry, X-ray diffraction, electron microprobe and porosity-permeability core analyses. These sandstones were deposited by a dryland river system, in a warm, mostly arid climate with episodic rainfall and high evaporation rates. During wetter periods especially feldspars were dissolved. Strong evaporation during dry periods led to reprecipitation of the dissolved species as K-feldspar and quartz overgrowths, smectite and calcite/dolomite. Sediment reworking resulted in framework grains becoming clay coated. The clay coats are better developed in finer than in coarser grained sediments. The original smectite composing the rims converted to illite during burial. The tangential orientation of the clay platelets in the rims led to illite-mica-induced dissolution of quartz during burial/compaction, which is manifested as bedding parallel dissolution seams that are filled with clays and micas, especially in the fine-grained sandstone/siltstone/claystone. These constitute important barriers to the vertical flow within the reservoir. The released silica did not really affect the red sandstones but was exported (often on mm to cm scale) to nearby bleached horizons, where nucleation inhibiting clay rims are less well developed. The red colour of the sandstones arises from the presence of small amounts of Fe-oxides in the inherited clay rims. Migration of fluids enriched in organic acids, expelled from underlying Carboniferous coal-bearing strata, resulted in local bleaching of coarser grained horizons. In the finer grained sediments, the red colour was mostly preserved, which suggests that the reductive capacity of the fluid was limited.

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Investigations on the shale oil and gas potential of Westphalian mudstone successions in the Campine Basin, NE Belgium (well KB174): Palaeoenvironmental and palaeogeographical controls

Cited by 6 publications

References 32 publications

High-Pressure Methane Sorption on Dry and Moisture-Equilibrated Shales

High-Pressure Methane Sorption on Dry and Moisture-Equilibrated Shales

Supercritical Methane Sorption on Organic-Rich Shales over a Wide Temperature Range

Reservoir characteristics and diagenesis of the Buntsandstein sandstones in the Campine Basin (NE Belgium)

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