Pore structure of transitional shales in the Ordos Basin, NW China: Effects of composition on gas storage capacity

[Display omitted] •Pore structure of transitional shale and organic matter is measured by N2, CO2 isotherms.•Both organic and inorganic grains develop micro-, meso- and macropores in gas window.•Clay minerals control specific surface area and absorbed gas at over-mature stage.•High TOC increases mic...

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Bibliographic Details
Published in:Fuel (Guildford) 2017-10, Vol.206 (C), p.504-515
Main Authors: Xiong, Fengyang, Jiang, Zhenxue, Li, Peng, Wang, Xiangzeng, Bi, He, Li, Yirun, Wang, Ziyuan, Amooie, Mohammad Amin, Soltanian, Mohamad Reza, Moortgat, Joachim
Format: Article
Language:English
Subjects:
Adsorption
Carbon dioxide
Carboniferous
Clay minerals
Coastal environments
Composition
Composition effects
Geochemistry
Inorganic matter
Kerogen
Low pressure
Membrane permeability
Minerals
Nitrogen
Oil shale
Ordos Basin
Organic carbon
Organic matter
Paleozoic
Permeability
Permian
Pore structure
Pores
Porosity
Pressure
Quartz
Reflectance
Shale
Shale gas
Shales
Silt
Storage
Storage capacity
Surface area
Total organic carbon
Transitional shales
Yanchang area
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Summary:[Display omitted] •Pore structure of transitional shale and organic matter is measured by N2, CO2 isotherms.•Both organic and inorganic grains develop micro-, meso- and macropores in gas window.•Clay minerals control specific surface area and absorbed gas at over-mature stage.•High TOC increases micropore volume at high depth, while total pore volume decreases. The recoverable resource of shale gas is 25 trillion cubic meter, 33% of which is stored in transitional shales in China. This work investigates the effects of organic and inorganic compositions on the development of Upper Paleozoic transitional shale pore structures through a combination of petrophysical and geochemical measurements. 42 shale samples were collected from marsh-lagoon and coastal delta settings in the Ordos Basin, NW China. The samples include the Upper Permian Shanxi shale (average total organic carbon (TOC) of 1.58wt%, Type III kerogen, average vitrinite reflectance (Ro) 2.6%), and the Upper Carboniferous Benxi shale (average TOC of 1.91wt%, Type III kerogen, average Ro 2.74%) at the over-mature stage or dry gas window. An important characteristic of these shales is the large proportion of clay minerals (∼69% in Benxi shale and 54% in Shanxi shale). The quartz content is ∼17% and 40% for Benxi and Shanxi shales, respectively. The pore structure of three samples and one isolated kerogen sample is analyzed via both low-pressure nitrogen and carbon dioxide adsorption methods. Low pressure nitrogen adsorption experiments show that Benxi and Shanxi shales characterized by ultra-low porosity and permeability develop mainly silt-shaped pores and potentially ink-bottle-shaped pores. We find that increasing fractions of organic matter (OM) result in a decrease in both total pore volume and specific surface area (SSA). Low pressure carbon dioxide adsorption experiments show that micropore volumes nonlinearly increase with increasing OM, although the contribution of organic micropore volume is limited. The mesopore and macropore volumes of inorganic compositions contribute mostly to the total pore volume. The OM in transitional shales in Yanchang mainly develop mesopores (with
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2017.05.083