Production Analysis of Tight-Gas and Shale-Gas Reservoirs Using the Dynamic-Slippage Concept

Clarkson, Christopher R.; Nobakht, Morteza; Kaviani, Danial; Ertekin, Turgay

doi:10.2118/144317-pa

Cited by 131 publications

(38 citation statements)

References 19 publications

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“…When modelling production from gas reservoirs, the flow enhancement through the gas slippage effect can become important during the final stages of production when pressures as low as 1 MPa may be reached (Clarkson et al 2012b). …”

Section: Introductionmentioning

confidence: 99%

Microstructural controls on the pressure-dependent permeability of Whitby mudstone

Mckernan

Mecklenburgh²,

Rutter³

et al. 2017

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A combination of permeability and ultrasonic velocity measurements allied with image analysis is used to distinguish the primary microstructural controls on effective-pressure dependent permeability. Permeabilities of cylindrical samples of Whitby Mudstone were measured using the oscillating pore pressure method at confining pressures ranging between 30-95 MPa and pore pressures ranging between 1-80 MPa. The permeability-effective pressure relationship is empirically described using a modified effective pressure law in terms of confining pressure, pore pressure and a Klinkenberg effect. Measured permeability ranges between 3×10 -21 m 2 and 2 ×10 -19 m 2 (3 and 200 nd), and decreases by ~1 order of magnitude across the applied effective pressure range. Permeability is shown to be less sensitive to changes in pore pressure than changes in confining pressure, yielding permeability effective pressure coefficients ( ) between 0.42 and 0.97. Based on a pore-conductivity model which considers the measured changes in acoustic wave velocity and pore volume with pressure, the observed loss of permeability with increasing effective pressure is attributed dominantly to the progressive closure of bedding-parallel, crack-like pores associated with grain boundaries.Despite only constituting a fraction of the total porosity, these pores form an interconnected network that significantly enhances permeability at low effective pressures.The pre-publication reference is: Mckernan, R., Mecklenburgh, J., Rutter, E. H. and Taylor Progress in understanding fluid transport properties of mudstones is currently hindered by a scarcity of published experimental data. However, the ongoing expansion of the hydrocarbon industry into low-permeability unconventional resources is driving the demand for research and development in this field. Even when hydraulic fracture treatment is used to enhance production, flow of hydrocarbons into the fractures will be controlled ultimately by the microporous, low permeability matrix. Furthermore, during reservoir production pore-fluid pressure is progressively reduced, which acts to increase the in-situ Terzaghi effective pressure (defined as overburden pressure minus pore pressure), thereby decreasing permeability. The evolution of permeability of the matrix therefore determines the prediction of long-term production, which must take into account the effects of flow regime, multiphase flow, sorption effects, permeability anisotropy and, most importantly, the pressuredependence of permeability.Laboratory measurements of permeability of intact mudstone samples performed under reservoir conditions has yielded values between 10 -22 m 2 and 10 -12 m 2 (0.1 nD and 1 D) for flow both parallel and normal to layering (Morrow et al.

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Section: Introductionmentioning

confidence: 99%

Microstructural controls on the pressure-dependent permeability of Whitby mudstone

Mckernan

Mecklenburgh²,

Rutter³

et al. 2017

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“…30,31 Such empirical corrections can not capture the complex adsorption and transport behavior of the uid in ultraconning porous materials. 32 Falk et al demonstrated that the non-Darcy behavior results from strong adsorption in kerogen and the breakdown of hydrodynamics at the nanoscale.…”

Section: 28mentioning

confidence: 99%

Pressure-driven supercritical CO₂transport through a silica nanochannel

Liu

et al. 2018

RSC Adv.

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A thorough understanding of supercritical CO 2 (scCO 2 ) transport through nanochannels is of prime significance for the effective exploitation of shale resources and the mitigation of greenhouse gas emission. In this work, we employed the non-equilibrium molecular dynamics simulations method to investigate the pressure-driven scCO 2 transport behavior through silica nanochannels with different external forces and pore sizes. The simulations reveal that the capability of scCO 2 diffusion enhances both in the bulk region and the surface adsorbed layer with the increasing of pressure gradient or nanochannel size, in addition, the slip length increases nonlinearly with the external acceleration or nanochannel width increases and finally reaches a maximum value. The negative slippage occurs at lower pressure gradient or within the narrower nanochannel. Overall, it is the combined effect of strong adsorption, surface diffusion and slippage that causes the nonlinear relation between flow rate and pressure gradient or nanochannel size. The present work would provide theoretical guidance for the scCO 2 enhanced shale oil/gas recovery, CO 2 storage, and mass transport in nanoporous materials.

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“…Review articles that were surveyed focused on the technical aspects related to fracking such as fracturing fluid systems and factors influencing fracture propagation (Mahrer, 1999;Rahman and Rahman, 2010;Vatsa and Wang, 2013;Barati and Liang, 2014;) and the economic aspects of these oil and gas resources such as resource availability, estimates and productivity (Clarkson et al, 2012 andMcGlade et al, 2013). These aspects are all important for the optimization of production from unconventional deposits.…”

Section: Box 1: Brief History Of Oil and Gas In South Africamentioning

confidence: 99%

A review of biophysical and socio-economic effects of unconventional oil and gas extraction – Implications for South Africa

Esterhuyse

Avenant

Redelinghuys

et al. 2016

Journal of Environmental Management

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The impacts associated with unconventional oil and gas (UOG) extraction will be cumulative in nature and will most likely occur on a regional scale, highlighting the importance of using strategic decision-making and management tools. Managing possible impacts responsibly is extremely important in a water scarce country such as South Africa, versus countries where more water may be available for UOG extraction activities. This review article explains the possible biophysical and socioeconomic impacts associated with UOG extraction within the South African context and how these complex impacts interlink. Relevant policy and governance frameworks to manage these impacts are also highlighted.

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Production Analysis of Tight-Gas and Shale-Gas Reservoirs Using the Dynamic-Slippage Concept

Cited by 131 publications

References 19 publications

Microstructural controls on the pressure-dependent permeability of Whitby mudstone

Microstructural controls on the pressure-dependent permeability of Whitby mudstone

Pressure-driven supercritical CO₂transport through a silica nanochannel

A review of biophysical and socio-economic effects of unconventional oil and gas extraction – Implications for South Africa

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Production Analysis of Tight-Gas and Shale-Gas Reservoirs Using the Dynamic-Slippage Concept

Cited by 131 publications

References 19 publications

Microstructural controls on the pressure-dependent permeability of Whitby mudstone

Microstructural controls on the pressure-dependent permeability of Whitby mudstone

Pressure-driven supercritical CO2transport through a silica nanochannel

A review of biophysical and socio-economic effects of unconventional oil and gas extraction – Implications for South Africa

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Product

Resources

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Pressure-driven supercritical CO₂transport through a silica nanochannel