Abstract
Pore structures with rich nanopores and permeability in tight gas reservoirs are poorly understood up to date. Advanced techniques are needed to be employed to accurately characterize pore structures, especially tiny pores which include micron and nanopores. In this study, various experimental techniques such as scanning electron microscopy (SEM), nuclear magnetic resonance (NMR) T 2 , nitrogen adsorption method, and NMR cryoporometry (NMRC) are combined to interrogate the complex pore systems of the tight gas reservoir in the Linxing formation, Ordos Basin, China. Results show that tight gas sandstones are primarily comprised of residual interparticle and clay-dominated pores. Clay and quartz are two dominate minerals while pyrite occupies a nontrivial amount as well. The permeability of tight gas sandstones is very low, exhibiting an extremely poor positive correlation with porosity. While pore types and relative pore contents are more influential factors on the permeability, accurate characterization of pore size distribution is critical for the permeability of tight gas sandstones. Therefore, complementary characterization methods are carried out, indicating that neither small pores with radii < 100 nm (around peak 1 in NMR T 2 distribution) nor large pores with radii > 5 μ m (around peak 3 in NMR T 2 distribution) control the permeability by analyzing the connectivity of the pores in various size ranges, but rather pores averaging approximately 350 ± X nm (around peak 2 in NMR T 2 distribution) have sufficient connectivity to host and transmit hydrocarbons. The pore size of tight gas sandstones is dominated by the clay-rich mineral assemblage. The study shows that the NMRC technique can be a very promising method, especially when referred to as a promising “roadmap” on how to interrogate tight formations such as the tight gas sands or even shale especially for the nanopore characterization.
Highlights
With the gradual depletion of conventional oil and gas systems, unconventional reservoirs have become the focus of the energy market
The purpose of this study is to explore the application of NMR cryoporometry (NMRC) on tight gas sandstone samples with different magnitudes of permeability collected from Linxing tight gas sandstone reservoirs, China
A comparison of results from nitrogen adsorption and NMRC is shown in Figures 7 and 8, respectively, indicating that pore size distributions determined by NMRC exhibit higher pore volumes relative to those from nitrogen adsorption
Summary
With the gradual depletion of conventional oil and gas systems, unconventional reservoirs have become the focus of the energy market. A tight gas sandstone reservoir is an important member [1, 2]. Low permeability reservoirs developed in the past are mostly sandstones. Whether a gas reservoir qualifies as tight or not depends on both physical and economic factors, as with tight oil sandstones, tight gas is associated with low porosity (
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