Threshold Pressure Phenomena in Porous Media

Thomas, L.K.; Katz, Donald L.; Tek, M.R.

doi:10.2118/1816-pa

Cited by 202 publications

(116 citation statements)

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“…This is similar to the empirical relationship proposed by Thomas et al (1968). If the confinement reduces the pore mean diameter d and does not affect the internal structure or connectivity of the porous structure, relation (15) is valid.…”

Section: Entry Pressuresupporting

confidence: 83%

Advanced and Integrated Petrophysical Characterization for CO₂Storage: Application to the Ketzin Site

Fleury

Gautier

Gland

et al. 2013

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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Re´sume´-Caracte´risation pe´trophysique inte´gre´e pour le stockage de CO 2 : application au site de Ketzin -La simulation et le suivi d'un stockage de CO 2 requiert des donne´es pe´trophysiques spe´cifiques. Nous pre´sentons un ensemble d'expe´riences applicables a`tout stockage et a`toute couverture, fournissant des donne´es pour des simulations nume´riques re´alistes du potentiel de stockage et de l'injection. Ces expe´riences sont inte´gre´es avec les donne´es diagraphiques pour l'estimation de la porosite´, la saturation irre´ductible, la pression capillaire et la perme´abiliteŕ elative de l'eau en drainage, la saturation en gaz re´siduelle, les relations re´sistivite´-saturation et les proprie´te´s de transport de la couverture (perme´abilite´et diffusivite´). Le cas conside´re´est l'aquife`re salin du Trias dans le contexte du projet CO 2 SINK, le premier site expe´rimental de stockage en Allemagne situe´pre`s de Ketzin.Nous avons utilise´des me´thodes de mesure ne´cessitant des dure´es raisonnables tout en restant repre´sentatives des processus in situ. Pour le transport diphasique, nous avons utilise´la centrifugation. Pour la re´sistivite´, nous avons utilise´une me´thode rapide « Fast Resistivity Index Measurement » (FRIM) en drainage et imbibition, en condition ambiante et en condition de stockage. Pour la caracte´risation de la couverture, nous avons utilise´une technique rapide RMN (Re´sonance Magne´tique Nucle´aire) utilisant le deute´rium comme traceur pour la mesure de diffusion et une me´thode stationnaire innovante pour la mesure de perme´abilite´. La pression d'entre´e a e´galement e´te´e´value´e. Les diagraphies RMN et de re´sistivite´ont e´galement e´te´utilise´es pour estimer de manie`re continue la saturation irre´ductible et juger de la repre´sentativite´des e´chantillons analyse´s au laboratoire.Pour le site de Ketzin, la zone de stockage est un gre`s argileux d'origine fluviatile localement tre`s cimente´d'une porosite´d'environ 30 % et d'une perme´abilite´variant de 100 a`300 mD. Deux zones se distinguent par des saturations irre´ductibles variant de 15 a`35 %. La courbe de perme´abilite´relative a`l'eau pre´sente une forte pente et sugge`re qu'une saturation infe´rieure a5 0 % n'est pas atteignable en pratique. L'exposant de saturation de l'indice de re´sistivite´est de 1,7, plus faible que la valeur standard de 2. La couverture a une perme´abilite´de 27 nD, une porosite´de 15 % et une diffusivite´de 0,8 9 10 À9 m 2 /s. Abstract -Advanced and Integrated Petrophysical Characterization for CO 2 Storage: Application to the Ketzin Site -Reservoir simulations and monitoring of CO 2 storage require specific petrophysical data. We show a workflow that can be applied to saline aquifers and caprocks in order to provide the minimum data set for realistic estimations of storage potential and perform pertinent simulations of CO 2 injection. The presented series of experiments are fully integrated with quantitative log data analysis to estimate porosity, irreducible saturation, drainage capillar...

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Section: Entry Pressuresupporting

confidence: 83%

Advanced and Integrated Petrophysical Characterization for CO₂Storage: Application to the Ketzin Site

Fleury

Gautier

Gland

et al. 2013

Oil Gas Sci. Technol. – Rev. IFP Energies nouvelles

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“…Due to lack of data for the capillary and displacement properties, the semianalytical correlations of Huet et al [2005], which relate the Brooks and Corey model parameters to porosity and permeability, were used to determine the values of the gas entry pressure p e and the pore size distribution index k. Similar values of the gas entry pressure p e were also obtained using the empirical models of Thomas et al [1968] and Hawkins et al [1993]. Since no data were available for the irreducible liquid and residual gas saturations in the Utica shale and Lorraine Group, they were assumed equal to 20% and 0%, respectively, for all simulations.…”

Section: 1002/2014wr016146mentioning

confidence: 99%

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

Nowamooz

Lemieux

Molson

et al. 2015

Water Resources Research

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Methane and brine leakage rates and associated time scales along the cemented casing of a hypothetical decommissioned shale gas well have been assessed with a multiphase flow and multicomponent numerical model. The conceptual model used for the simulations assumes that the target shale formation is 200 m thick, overlain by a 750 m thick caprock, which is in turn overlain by a 50 m thick surficial sand aquifer, the 1000 m geological sequence being intersected by a fully penetrating borehole. This succession of geological units is representative of the region targeted for shale gas exploration in the St. Lawrence Lowlands (Qu ebec, Canada). The simulations aimed at assessing the impact of well casing cementation quality on methane and brine leakage at the base of a surficial aquifer. The leakage of fluids can subsequently lead to the contamination of groundwater resources and/or, in the case of methane migration to ground surface, to an increase in greenhouse gas emissions. The minimum reported surface casing vent flow (measured at ground level) for shale gas wells in Quebec (0.01 m 3 /d) is used as a reference to evaluate the impact of well casing cementation quality on methane and brine migration. The simulations suggest that an adequately cemented borehole (with a casing annulus permeability k c 1 mD) can prevent methane and brine leakage over a time scale of up to 100 years. However, a poorly cemented borehole (k c ! 10 mD) could yield methane leakage rates at the base of an aquifer ranging from 0.04 m 3 /d to more than 100 m 3 /d, depending on the permeability of the target shale gas formation after abandonment and on the quantity of mobile gas in the formation. These values are compatible with surface casing vent flows reported for shale gas wells in the St. Lawrence Lowlands (Quebec, Canada). The simulated travel time of methane from the target shale formation to the surficial aquifer is between a few months and 30 years, depending on cementation quality and hydrodynamic properties of the casing annulus. Simulated longterm brine leakage rates after 100 years for poorly cemented boreholes are on the order of 10 25 m 3 /d (10 mL/d) to 10 23 m 3 /d (1 L/d). Based on scoping calculations with a well-mixed aquifer model, these rates are unlikely to have a major impact on groundwater quality in a confined aquifer since they would only increase the chloride concentration in a pristine aquifer to 1 mg/L, which is significantly below the commonly recommended aesthetic objective of 250 mg/L for chloride.

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“…Regardless from the adopted experimental procedure, threshold pressure evaluation via lab analysis is always time-consuming (in the order of days or even weeks) due to the poor fluid transport property of the tested fine-grained caprocks. Consequently, different experimental and theoretical relations between threshold pressure values and petrophysical rock properties, such as permeability, porosity and formation resistivity, have also been developed [15][16][17]. However, even if these correlations represent a cheap and prompt alternative for a first-guess parameter estimation, only lab analyses can provide a reliable threshold pressure evaluation.…”

Section: Threshold Pressurementioning

confidence: 99%

What’s Conventional and What’s Special in a Reservoir Study for Underground Gas Storage

Verga

2018

Energies

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Abstract:The development of an underground gas storage (UGS) project and its subsequent management must ensure technical feasibility, commercial value and long-term efficiency. The UGS industry has borrowed much of its knowledge from other disciplines (primarily oil and gas reservoir engineering), but it has also developed its own technology. This paper provides a methodological approach based on current practices and available methods for designing and safely operating a UGS (including the so-called "delta-pressure" option to enhance UGS performance) and highlights what is special in UGS compared to oil and gas reservoirs.

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Threshold Pressure Phenomena in Porous Media

Cited by 202 publications

References 0 publications

Advanced and Integrated Petrophysical Characterization for CO₂Storage: Application to the Ketzin Site

Advanced and Integrated Petrophysical Characterization for CO₂Storage: Application to the Ketzin Site

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

What’s Conventional and What’s Special in a Reservoir Study for Underground Gas Storage

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Threshold Pressure Phenomena in Porous Media

Cited by 202 publications

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Advanced and Integrated Petrophysical Characterization for CO2Storage: Application to the Ketzin Site

Advanced and Integrated Petrophysical Characterization for CO2Storage: Application to the Ketzin Site

Numerical investigation of methane and formation fluid leakage along the casing of a decommissioned shale gas well

What’s Conventional and What’s Special in a Reservoir Study for Underground Gas Storage

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Product

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Advanced and Integrated Petrophysical Characterization for CO₂Storage: Application to the Ketzin Site

Advanced and Integrated Petrophysical Characterization for CO₂Storage: Application to the Ketzin Site