Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China

Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China

The purpose of this paper is to probe into the nature and variability in vertical microstructure within Longmaxi gas shales of well WX2, Lower Silurian, located in the NE Sichuan Basin of China. To understand the pore system of these rocks, the total porosity, pore size distribution (PSD), surface a...

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Main Authors: Shasha Sun, Feng Liang, Ligen Tang, Jin Wu, Chao Ma
Format: Article
Language:English
Published: SAGE Publishing 2017-07-01
Series:Energy Exploration & Exploitation
Online Access:https://doi.org/10.1177/0144598716684304
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spelling doaj-5215d5c802b249b2979479b1015f23c02020-11-25T04:09:54ZengSAGE PublishingEnergy Exploration & Exploitation0144-59872048-40542017-07-013510.1177/0144598716684304Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, ChinaShasha Sun0Feng Liang1Ligen Tang2Jin Wu3Chao Ma4Unconventional Oil and Gas Laboratory of Petrochina, Langfang, Hebei, ChinaUnconventional Oil and Gas Laboratory of Petrochina, Langfang, Hebei, ChinaPetrochina Research Institute of Petroleum Exploration and Development-Langfang, Langfang, Hebei, ChinaUnconventional Oil and Gas Laboratory of Petrochina, Langfang, Hebei, ChinaUnconventional Oil and Gas Laboratory of Petrochina, Langfang, Hebei, ChinaThe purpose of this paper is to probe into the nature and variability in vertical microstructure within Longmaxi gas shales of well WX2, Lower Silurian, located in the NE Sichuan Basin of China. To understand the pore system of these rocks, the total porosity, pore size distribution (PSD), surface area, organic geochemistry, and mineralogy, some image analyses by electron microscopy are performed. The obtained results indicated the following. (1) Gas shales have a complex pore structure. Total porosity from helium pycnometry ranges between 0.75% and 4.62%. Total organic content ranges between 3.4 wt.% and 11 wt.%, and vitrinite reflectance measured between 2.5% and 3.1%. The gas shales are quartz and clay rich. (2) Focused ion beam milling and field emission scanning electron microscopy provide high-resolution images of pores distribution and types. Three primary types of pores, organic matter (OM)-hosted pores, mineral-hosted pores, and micro-fractures, and 11 subgroups have been recognized. (3) The N 2 isotherm curves are grouped into two types, II b as well as IV a, with the hysteresis loop belonging to Type B, reflecting the morphology of slits pores, and Type A, presenting cylinder pores. Combination of N 2 and CO 2 isotherm curve shows bimodal in two diameter sections, 0.3–1 nm and 2–5 nm, revealing meso-pores play important role in pore volume, whereas the micro-pores have great influence on pore specific surface area. (4) Total organic carbon (TOC) is considered to be the dominant contributor to total porosity and pore types, with the proportion of OM-hosted pores following the upward decreasing tendency of TOC. In plane, pore types are controlled by sedimentary facies. The OM-hosted pores are more prevalent in deep shelf facies within lower part of shale other than upper formation, instead of shallow shelf facies.https://doi.org/10.1177/0144598716684304
collection DOAJ
language English
format Article
sources DOAJ
author Shasha Sun
Feng Liang
Ligen Tang
Jin Wu
Chao Ma
spellingShingle Shasha Sun
Feng Liang
Ligen Tang
Jin Wu
Chao Ma
Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China
Energy Exploration & Exploitation
author_facet Shasha Sun
Feng Liang
Ligen Tang
Jin Wu
Chao Ma
author_sort Shasha Sun
title Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China
title_short Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China
title_full Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China
title_fullStr Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China
title_full_unstemmed Microstructural investigation of gas shale in Longmaxi Formation, Lower Silurian, NE Sichuan Basin, China
title_sort microstructural investigation of gas shale in longmaxi formation, lower silurian, ne sichuan basin, china
publisher SAGE Publishing
series Energy Exploration & Exploitation
issn 0144-5987
2048-4054
publishDate 2017-07-01
description The purpose of this paper is to probe into the nature and variability in vertical microstructure within Longmaxi gas shales of well WX2, Lower Silurian, located in the NE Sichuan Basin of China. To understand the pore system of these rocks, the total porosity, pore size distribution (PSD), surface area, organic geochemistry, and mineralogy, some image analyses by electron microscopy are performed. The obtained results indicated the following. (1) Gas shales have a complex pore structure. Total porosity from helium pycnometry ranges between 0.75% and 4.62%. Total organic content ranges between 3.4 wt.% and 11 wt.%, and vitrinite reflectance measured between 2.5% and 3.1%. The gas shales are quartz and clay rich. (2) Focused ion beam milling and field emission scanning electron microscopy provide high-resolution images of pores distribution and types. Three primary types of pores, organic matter (OM)-hosted pores, mineral-hosted pores, and micro-fractures, and 11 subgroups have been recognized. (3) The N 2 isotherm curves are grouped into two types, II b as well as IV a, with the hysteresis loop belonging to Type B, reflecting the morphology of slits pores, and Type A, presenting cylinder pores. Combination of N 2 and CO 2 isotherm curve shows bimodal in two diameter sections, 0.3–1 nm and 2–5 nm, revealing meso-pores play important role in pore volume, whereas the micro-pores have great influence on pore specific surface area. (4) Total organic carbon (TOC) is considered to be the dominant contributor to total porosity and pore types, with the proportion of OM-hosted pores following the upward decreasing tendency of TOC. In plane, pore types are controlled by sedimentary facies. The OM-hosted pores are more prevalent in deep shelf facies within lower part of shale other than upper formation, instead of shallow shelf facies.
url https://doi.org/10.1177/0144598716684304
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