R. Marc Bustin scite author profile

Permeability and diffusivity are critical parameters of tight reservoir rocks that determine their viability for commercial development. Current methods for measuring permeability and ⁄ or diffusivity may lead to erroneous results when applied to very tight rocks including gas shales, coal, and tight gas sands, as well as rocks considered as seals for nuclear waste repositories and strata for geological sequestration of CO 2 . The use of He as routinely applied to measure porosity, permeability, and diffusivity may result in non-systematic errors because of the molecular sieving effect of the fine pore structure to larger molecules such as reservoir gases. Utilizing gases with larger adsorption potentials than He, such as N 2 , and including all reservoir gases to measure porosity or permeability of rocks with high surface area is a viable alternative, but requires correcting for adsorption in the analyses. This study expands several approaches to measure permeability and diffusivity with considerations for gas adsorption, which has not been explicitly considered in previous studies. We present new models that explicitly correct for adsorption during pulse-decay measurements of core under reservoir conditions, as well as on crushed samples used to approximate permeability or diffusivity. We also present a method to determine permeability or diffusivity from on-site drill-core desorption test data as carried out to determine gas in place in coals or gas shales. Our new approach utilizes late-time data from experimental pressure-decay tests, which we show to be more reliable and theoretically (and practically) accurate than the early-time approach commonly used to estimate gastransport properties.

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Volumetric strain associated with methane desorption and its impact on coalbed gas production from deep coal seams

Cui¹,

Bustin²

2005

Bulletin

578

339

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Characterizing the shale gas resource potential of Devonian–Mississippian strata in the Western Canada sedimentary basin: Application of an integrated formation evaluation

Ross¹,

Bustin²

2008

Bulletin

587

323

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Selective transport of CO2, CH4, and N2 in coals: insights from modeling of experimental gas adsorption data

Cui

Bustin

Dipple

2004

Fuel

455

298

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Lower Cretaceous gas shales in northeastern British Columbia, Part I: geological controls on methane sorption capacity

Chalmers

Bustin

2008

Bulletin of Canadian Petroleum Geology

515

289

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R. Marc Bustin

The importance of shale composition and pore structure upon gas storage potential of shale gas reservoirs

Pore structure characterization of North American shale gas reservoirs using USANS/SANS, gas adsorption, and mercury intrusion

Characterization of gas shale pore systems by porosimetry, pycnometry, surface area, and field emission scanning electron microscopy/transmission electron microscopy image analyses: Examples from the Barnett, Woodford, Haynesville, Marcellus, and Doig units

Measurements of gas permeability and diffusivity of tight reservoir rocks: different approaches and their applications

Volumetric strain associated with methane desorption and its impact on coalbed gas production from deep coal seams

Characterizing the shale gas resource potential of Devonian–Mississippian strata in the Western Canada sedimentary basin: Application of an integrated formation evaluation

Selective transport of CO2, CH4, and N2 in coals: insights from modeling of experimental gas adsorption data

Lower Cretaceous gas shales in northeastern British Columbia, Part I: geological controls on methane sorption capacity

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