TY - JOUR
T1 - Diagenetic sequences of continuously deposited tight sandstones in various environments
T2 - A case study from upper Paleozoic sandstones in the Linxing area, eastern Ordos basin, China
AU - Li, Yong
AU - Li, Yong
AU - Gao, Xiangdong
AU - Meng, Shangzhi
AU - Wu, Peng
AU - Niu, Xinlei
AU - Qiao, Peng
AU - Elsworth, Derek
N1 - Funding Information:
We would like to thank AAPG Editor Barry J. Katz for his careful revisions and great suggestions in improving the manuscript. This research was financially supported by the Natural Science Foundation of China (grant 41702171), Beijing Municipal Excellent Talents Foundation (2017000020124G107), 2017 Open Project Fund of State Key Laboratory of Coal Resources and Safe Mining (SKLCRSM17KFA12). We also thank China United Coalbed Methane Corp., Ltd., for providing convenient access to the field work and well test reports.
Publisher Copyright:
© 2019 The American Association of Petroleum Geologists. All rights reserved.
PY - 2019/11
Y1 - 2019/11
N2 - An integrated analysis of the petrographic characteristics and types and distribution of diagenetic alteration in the upper Paleozoic Benxi-Taiyuan, Shanxi, and Xiashihezi Formations provides insights into the controlling factors on variations in porosity and permeability in tight sandstones (85% of the sandstone samples display porosity values <10% and 90% of the samples exhibit permeability <1 md). Diagenetic alteration includes mesogenetic compaction, cementation by dolomite, ankerite, and quartz, dissolution of feldspar, and illitization of smectite. Eodiagenesis includes compaction, development of smectite, cementation by pore-filling quartz and disordered kaolinite, and precipitation of calcite and Fe-calcite. Chlorite and quartz preserve primary pores against damage, whereas kaolinite, illite-smectite (I/S) mixed layer, and illite significantly diminish reservoir quality via permeability reduction. Chlorite and I/S content decrease abruptly as depth increases, whereas the kaolinite content remains elevated at depth because of the complete destruction of K-feldspar. The transformation from smectite to illite provides silica ions for the widely distributed quartz overgrowths. As the depositional environment transformed from fluvial (Xiashihezi) to deltaic (Shanxi) and to epicontinental (Taiyuan and Benxi), the dissolution effect increased monotonically. Feldspar dissolution is dominant in the Shanxi Formation,whereas the Benxi and Taiyuan Formations commonly contain quartz dissolution pores. The Taiyuan Formation has markedly higher porosities than in the overlying and underlying formations, caused by strong dissolution and high silica content. The decrease in porosity in the Benxi Formation results from the extensive formation of clay minerals caused by high frequency transgressions in a transitional environment.
AB - An integrated analysis of the petrographic characteristics and types and distribution of diagenetic alteration in the upper Paleozoic Benxi-Taiyuan, Shanxi, and Xiashihezi Formations provides insights into the controlling factors on variations in porosity and permeability in tight sandstones (85% of the sandstone samples display porosity values <10% and 90% of the samples exhibit permeability <1 md). Diagenetic alteration includes mesogenetic compaction, cementation by dolomite, ankerite, and quartz, dissolution of feldspar, and illitization of smectite. Eodiagenesis includes compaction, development of smectite, cementation by pore-filling quartz and disordered kaolinite, and precipitation of calcite and Fe-calcite. Chlorite and quartz preserve primary pores against damage, whereas kaolinite, illite-smectite (I/S) mixed layer, and illite significantly diminish reservoir quality via permeability reduction. Chlorite and I/S content decrease abruptly as depth increases, whereas the kaolinite content remains elevated at depth because of the complete destruction of K-feldspar. The transformation from smectite to illite provides silica ions for the widely distributed quartz overgrowths. As the depositional environment transformed from fluvial (Xiashihezi) to deltaic (Shanxi) and to epicontinental (Taiyuan and Benxi), the dissolution effect increased monotonically. Feldspar dissolution is dominant in the Shanxi Formation,whereas the Benxi and Taiyuan Formations commonly contain quartz dissolution pores. The Taiyuan Formation has markedly higher porosities than in the overlying and underlying formations, caused by strong dissolution and high silica content. The decrease in porosity in the Benxi Formation results from the extensive formation of clay minerals caused by high frequency transgressions in a transitional environment.
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U2 - 10.1306/03061918062
DO - 10.1306/03061918062
M3 - Article
AN - SCOPUS:85083667282
SN - 0149-1423
VL - 103
SP - 2757
EP - 2783
JO - AAPG Bulletin
JF - AAPG Bulletin
IS - 11
ER -