Hydrothermal silicification and its impact on Lower–Middle Ordovician carbonates in Shunnan area, Tarim Basin, NW China

The Shunnan area is a newly discovered hydrocarbon field in Shuntuoguole lower uplift, in which the host rocks are Lower–Middle Ordovician carbonates. The carbonate reservoirs are well affected by hydrothermal silicification with well‐preserved intercrystalline pore of replacement quartz and megaqua...

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Veröffentlicht in:	Geological journal (Chichester, England) England), 2022-09, Vol.57 (9), p.3538-3557
Hauptverfasser:	Ye, Ning, Li, Yingtao, Huang, Baiwen, Xi, Binbin, Jiang, Hong, Lu, Ziye, Chen, Qianglu, You, Donghua, Xu, Jin
Format:	Artikel
Sprache:	eng
Schlagworte:	Calcite Carbonate rocks Carbonates Cementation Cements Chert Cherts Depth Diagenesis Evolution Fault detection Fractures Geological faults hydrothermal silicification Limestone Lithofacies Membrane permeability Mudstone Ordovician Permeability Petrography Petrology Pores Porosity Precursors Quartz reservoir quality Reservoirs secondary pore Silica Silicification Silicon dioxide Tarim Basin Temperature Uplift
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creator	Ye, Ning Li, Yingtao Huang, Baiwen Xi, Binbin Jiang, Hong Lu, Ziye Chen, Qianglu You, Donghua Xu, Jin
description	The Shunnan area is a newly discovered hydrocarbon field in Shuntuoguole lower uplift, in which the host rocks are Lower–Middle Ordovician carbonates. The carbonate reservoirs are well affected by hydrothermal silicification with well‐preserved intercrystalline pore of replacement quartz and megaquartz cements. Based on the petrography, pore types, and diagenetic processes, this research evaluated the reservoir quality and re‐constructed the porosity evolution in different diagenetic stages. Samples are collected from 7‐cored wells distributed along NNE‐ or ENE‐trending sinistral strike‐slip faults. Nine types of lithofacies were identified in the study area, including mudstone, bioclast wackestone, peloidal bioclast packstone, boundstone, peloidal grainstone, ooid grainstone, slightly silicified limestone (silica less than 25%), strongly silicified limestone (silica around 50%), and chert. Chert has better porosity (average 21.3%) and permeability (average 44.7 mD) than other lithofacies. The main reservoir pores are mainly developed in forms of fractures, intercrystalline replacement quartz and dissolved vugs. The porosity evolution shows that the primary porosity was limited due to cementation and compaction, and the earlier secondary porosity was occlusive as a result of coarse calcite cementation. Therefore, the precursor limestones may be tight, and the reservoir quality of the Lower–Middle Ordovician carbonates was controlled by hydrothermal silicification. During the hydrothermal silicification event, the burial depth of the Lower–Middle Ordovician carbonates was more than 3,000 m and their stratum temperature was higher than 120°C, representing a deep burial condition. The statistical data of porosity‐depth/temperature trends for carbonates suggest that the early secondary pores would be significantly reduced when the burial temperature reaches 100°C (or depth of strata reaches 3,000 m). Therefore, the dissolved vugs in strongly silicified limestone or hydrothermal chert are caused by hydrothermal silicification and not inherited from precursor carbonate rocks. The precursor limestones were tight, and the hydrothermal silicification significantly enhanced the reservoir properties of the deep carbonates and not inherited from precursor carbonates.
doi_str_mv	10.1002/gj.4482
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The carbonate reservoirs are well affected by hydrothermal silicification with well‐preserved intercrystalline pore of replacement quartz and megaquartz cements. Based on the petrography, pore types, and diagenetic processes, this research evaluated the reservoir quality and re‐constructed the porosity evolution in different diagenetic stages. Samples are collected from 7‐cored wells distributed along NNE‐ or ENE‐trending sinistral strike‐slip faults. Nine types of lithofacies were identified in the study area, including mudstone, bioclast wackestone, peloidal bioclast packstone, boundstone, peloidal grainstone, ooid grainstone, slightly silicified limestone (silica less than 25%), strongly silicified limestone (silica around 50%), and chert. Chert has better porosity (average 21.3%) and permeability (average 44.7 mD) than other lithofacies. The main reservoir pores are mainly developed in forms of fractures, intercrystalline replacement quartz and dissolved vugs. The porosity evolution shows that the primary porosity was limited due to cementation and compaction, and the earlier secondary porosity was occlusive as a result of coarse calcite cementation. Therefore, the precursor limestones may be tight, and the reservoir quality of the Lower–Middle Ordovician carbonates was controlled by hydrothermal silicification. During the hydrothermal silicification event, the burial depth of the Lower–Middle Ordovician carbonates was more than 3,000 m and their stratum temperature was higher than 120°C, representing a deep burial condition. The statistical data of porosity‐depth/temperature trends for carbonates suggest that the early secondary pores would be significantly reduced when the burial temperature reaches 100°C (or depth of strata reaches 3,000 m). Therefore, the dissolved vugs in strongly silicified limestone or hydrothermal chert are caused by hydrothermal silicification and not inherited from precursor carbonate rocks. 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The carbonate reservoirs are well affected by hydrothermal silicification with well‐preserved intercrystalline pore of replacement quartz and megaquartz cements. Based on the petrography, pore types, and diagenetic processes, this research evaluated the reservoir quality and re‐constructed the porosity evolution in different diagenetic stages. Samples are collected from 7‐cored wells distributed along NNE‐ or ENE‐trending sinistral strike‐slip faults. Nine types of lithofacies were identified in the study area, including mudstone, bioclast wackestone, peloidal bioclast packstone, boundstone, peloidal grainstone, ooid grainstone, slightly silicified limestone (silica less than 25%), strongly silicified limestone (silica around 50%), and chert. Chert has better porosity (average 21.3%) and permeability (average 44.7 mD) than other lithofacies. The main reservoir pores are mainly developed in forms of fractures, intercrystalline replacement quartz and dissolved vugs. The porosity evolution shows that the primary porosity was limited due to cementation and compaction, and the earlier secondary porosity was occlusive as a result of coarse calcite cementation. Therefore, the precursor limestones may be tight, and the reservoir quality of the Lower–Middle Ordovician carbonates was controlled by hydrothermal silicification. During the hydrothermal silicification event, the burial depth of the Lower–Middle Ordovician carbonates was more than 3,000 m and their stratum temperature was higher than 120°C, representing a deep burial condition. The statistical data of porosity‐depth/temperature trends for carbonates suggest that the early secondary pores would be significantly reduced when the burial temperature reaches 100°C (or depth of strata reaches 3,000 m). Therefore, the dissolved vugs in strongly silicified limestone or hydrothermal chert are caused by hydrothermal silicification and not inherited from precursor carbonate rocks. The precursor limestones were tight, and the hydrothermal silicification significantly enhanced the reservoir properties of the deep carbonates and not inherited from precursor carbonates.</description><subject>Calcite</subject><subject>Carbonate rocks</subject><subject>Carbonates</subject><subject>Cementation</subject><subject>Cements</subject><subject>Chert</subject><subject>Cherts</subject><subject>Depth</subject><subject>Diagenesis</subject><subject>Evolution</subject><subject>Fault detection</subject><subject>Fractures</subject><subject>Geological faults</subject><subject>hydrothermal silicification</subject><subject>Limestone</subject><subject>Lithofacies</subject><subject>Membrane permeability</subject><subject>Mudstone</subject><subject>Ordovician</subject><subject>Permeability</subject><subject>Petrography</subject><subject>Petrology</subject><subject>Pores</subject><subject>Porosity</subject><subject>Precursors</subject><subject>Quartz</subject><subject>reservoir quality</subject><subject>Reservoirs</subject><subject>secondary pore</subject><subject>Silica</subject><subject>Silicification</subject><subject>Silicon dioxide</subject><subject>Tarim Basin</subject><subject>Temperature</subject><subject>Uplift</subject><issn>0072-1050</issn><issn>1099-1034</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><recordid>eNp1kE1OwzAQhS0EEqUgrmCJBQuaYjvOj5dQQQsqdEERy2jiOK2j1Cl2SpUdd-CGnASXsmU1o6dvZt48hM4pGVJC2PWiGnKesgPUo0SIgJKQH6IeIQnzfUSO0YlzFSGUEk57qJt0hW3apbIrqLHTtZa61BJa3RgMpsC6dViv1iBb7JVps1X2-_PrSRdFrfDMFs2HnwCDJdi8MdAqjxv8stwY41WwCgZ4Dlav8C04bQb4-Q2PltrAKToqoXbq7K_20ev93Xw0Caaz8cPoZhpIlgoWMM64ABLxPFaMh9L_QQmASEUcJSWXMS0EY7JIchYyCEMRUiijhKs4L-O4DMM-utjvXdvmfaNcm1XNxhp_MmMJSVMWJWJHXe4paRvnrCqztfcMtssoyXa5Zosq2-Xqyas9udW16v7DsvHjL_0Du2h4Gg</recordid><startdate>202209</startdate><enddate>202209</enddate><creator>Ye, Ning</creator><creator>Li, Yingtao</creator><creator>Huang, Baiwen</creator><creator>Xi, Binbin</creator><creator>Jiang, Hong</creator><creator>Lu, Ziye</creator><creator>Chen, Qianglu</creator><creator>You, Donghua</creator><creator>Xu, Jin</creator><general>John Wiley & Sons, Inc</general><general>Wiley Subscription Services, Inc</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7ST</scope><scope>7UA</scope><scope>C1K</scope><scope>F1W</scope><scope>H96</scope><scope>L.G</scope><scope>SOI</scope><orcidid>https://orcid.org/0000-0001-7885-432X</orcidid><orcidid>https://orcid.org/0000-0002-3117-9109</orcidid></search><sort><creationdate>202209</creationdate><title>Hydrothermal silicification and its impact on Lower–Middle Ordovician carbonates in Shunnan area, Tarim Basin, NW China</title><author>Ye, Ning ; Li, Yingtao ; Huang, Baiwen ; Xi, Binbin ; Jiang, Hong ; Lu, Ziye ; Chen, Qianglu ; You, Donghua ; Xu, Jin</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c2892-24249a054b6e243c07210aa989657f4c61d922cd7b232a33931af574e6bf66f33</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2022</creationdate><topic>Calcite</topic><topic>Carbonate rocks</topic><topic>Carbonates</topic><topic>Cementation</topic><topic>Cements</topic><topic>Chert</topic><topic>Cherts</topic><topic>Depth</topic><topic>Diagenesis</topic><topic>Evolution</topic><topic>Fault detection</topic><topic>Fractures</topic><topic>Geological faults</topic><topic>hydrothermal silicification</topic><topic>Limestone</topic><topic>Lithofacies</topic><topic>Membrane permeability</topic><topic>Mudstone</topic><topic>Ordovician</topic><topic>Permeability</topic><topic>Petrography</topic><topic>Petrology</topic><topic>Pores</topic><topic>Porosity</topic><topic>Precursors</topic><topic>Quartz</topic><topic>reservoir quality</topic><topic>Reservoirs</topic><topic>secondary pore</topic><topic>Silica</topic><topic>Silicification</topic><topic>Silicon dioxide</topic><topic>Tarim Basin</topic><topic>Temperature</topic><topic>Uplift</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Ye, Ning</creatorcontrib><creatorcontrib>Li, Yingtao</creatorcontrib><creatorcontrib>Huang, Baiwen</creatorcontrib><creatorcontrib>Xi, Binbin</creatorcontrib><creatorcontrib>Jiang, Hong</creatorcontrib><creatorcontrib>Lu, Ziye</creatorcontrib><creatorcontrib>Chen, Qianglu</creatorcontrib><creatorcontrib>You, Donghua</creatorcontrib><creatorcontrib>Xu, Jin</creatorcontrib><collection>CrossRef</collection><collection>Environment Abstracts</collection><collection>Water Resources Abstracts</collection><collection>Environmental Sciences and Pollution Management</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy & Non-Living Resources</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><collection>Environment Abstracts</collection><jtitle>Geological journal (Chichester, England)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Ye, Ning</au><au>Li, Yingtao</au><au>Huang, Baiwen</au><au>Xi, Binbin</au><au>Jiang, Hong</au><au>Lu, Ziye</au><au>Chen, Qianglu</au><au>You, Donghua</au><au>Xu, Jin</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Hydrothermal silicification and its impact on Lower–Middle Ordovician carbonates in Shunnan area, Tarim Basin, NW China</atitle><jtitle>Geological journal (Chichester, England)</jtitle><date>2022-09</date><risdate>2022</risdate><volume>57</volume><issue>9</issue><spage>3538</spage><epage>3557</epage><pages>3538-3557</pages><issn>0072-1050</issn><eissn>1099-1034</eissn><abstract>The Shunnan area is a newly discovered hydrocarbon field in Shuntuoguole lower uplift, in which the host rocks are Lower–Middle Ordovician carbonates. The carbonate reservoirs are well affected by hydrothermal silicification with well‐preserved intercrystalline pore of replacement quartz and megaquartz cements. Based on the petrography, pore types, and diagenetic processes, this research evaluated the reservoir quality and re‐constructed the porosity evolution in different diagenetic stages. Samples are collected from 7‐cored wells distributed along NNE‐ or ENE‐trending sinistral strike‐slip faults. Nine types of lithofacies were identified in the study area, including mudstone, bioclast wackestone, peloidal bioclast packstone, boundstone, peloidal grainstone, ooid grainstone, slightly silicified limestone (silica less than 25%), strongly silicified limestone (silica around 50%), and chert. Chert has better porosity (average 21.3%) and permeability (average 44.7 mD) than other lithofacies. The main reservoir pores are mainly developed in forms of fractures, intercrystalline replacement quartz and dissolved vugs. The porosity evolution shows that the primary porosity was limited due to cementation and compaction, and the earlier secondary porosity was occlusive as a result of coarse calcite cementation. Therefore, the precursor limestones may be tight, and the reservoir quality of the Lower–Middle Ordovician carbonates was controlled by hydrothermal silicification. During the hydrothermal silicification event, the burial depth of the Lower–Middle Ordovician carbonates was more than 3,000 m and their stratum temperature was higher than 120°C, representing a deep burial condition. The statistical data of porosity‐depth/temperature trends for carbonates suggest that the early secondary pores would be significantly reduced when the burial temperature reaches 100°C (or depth of strata reaches 3,000 m). Therefore, the dissolved vugs in strongly silicified limestone or hydrothermal chert are caused by hydrothermal silicification and not inherited from precursor carbonate rocks. The precursor limestones were tight, and the hydrothermal silicification significantly enhanced the reservoir properties of the deep carbonates and not inherited from precursor carbonates.</abstract><cop>Hoboken, USA</cop><pub>John Wiley & Sons, Inc</pub><doi>10.1002/gj.4482</doi><tpages>20</tpages><orcidid>https://orcid.org/0000-0001-7885-432X</orcidid><orcidid>https://orcid.org/0000-0002-3117-9109</orcidid></addata></record>
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subjects	Calcite Carbonate rocks Carbonates Cementation Cements Chert Cherts Depth Diagenesis Evolution Fault detection Fractures Geological faults hydrothermal silicification Limestone Lithofacies Membrane permeability Mudstone Ordovician Permeability Petrography Petrology Pores Porosity Precursors Quartz reservoir quality Reservoirs secondary pore Silica Silicification Silicon dioxide Tarim Basin Temperature Uplift
title	Hydrothermal silicification and its impact on Lower–Middle Ordovician carbonates in Shunnan area, Tarim Basin, NW China
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