Characteristics of the S80 strike-slip fault zone and its controlling effects on the Ordovician reservoirs in the Tahe oilfield，Tarim Basin

被引：0

作者：

Han, Pengyuan ^{[1
,2
]}

Ding, Wenlong ^{[1
,2
]}

Yang, Debin ^{[1
,2
,3
]}

Zhang, Juan ^{[1
,2
,3
]}

Ma, Hailong ^{[3
]}

Wang, Shenghui ^{[1
,2
]}

机构：

[1] School of Energy Resources, China University of Geosciences（Beijing）, Beijing

[2] Key Laboratory of Marine Reservoir Evolution and Hydrocarbon Enrichment Mechanism, Ministry of Education, China University of Geosciences（Beijing）, Beijing

[3] Exploration and Development Research Institute, Northwest Oil Field Company, SINOPEC, Xinjiang, Urumqi

来源：

Oil and Gas Geology | 2024年 / 45卷 / 03期

关键词：

fault activity; fault segmentation; faulting-controled reservoir formation; Ordovician; S80 strike-slip fault zone; Tahe oilfield; Tarim Basin;

D O I：

10.11743/ogg20240314

中图分类号：

学科分类号：

摘要：

A fine interpretation of the S80 strike-slip fault zone in the Tahe area of Tarim Basin is carried out by comprehensively utilizing core data，logs，the widths and total volume of the lost intervals in individual wells，high-precision 3D seismic data，and multilayer coherence attributes. Its spatial distribution，and activity intensity and stages are determined thereby，and its controlling effects on the Ordovician reservoirs are explored. The findings indicate that the S80 strike-slip fault zone can be divided into the western，central，and eastern subzones along its strike. These three subzones generally show a noticeable increase in the number，length，and width of overlapping segments from the Cambrian to the Ordovician strata vertically. Laterally，the S80 strike-slip fault zone，from SW to NE，exhibits the contraction of its transtensional segments，the expansion of its transpressional segments，and the gradual disappearance of its pure strike-slip segment. Furthermore，the activity of this fault zone proves strong in its central subzone but weak in its western and eastern subzones. The S80 strike-slip fault zone experienced four activity stages，namely the Middle Caledonian，the Late Caledonian-Early Hercynian，the Late Hercynian，and the Indosinian-Early Himalayan，with the former two stages predominating. This fault zone experienced sinistral strike-slip in the former two stages but dextral in the latter two stages. Three types of reservoirs are developed along the S80 strike-slip fault zone：cavernous，compound （fractured-vuggy and vuggy-fractured types），and fractured types. The development of dissolution vugs is closely related to the segmented activity of strike-slip faults，with the transpressional and translational segments featuring strong activity，as well as the periphery of the major faults of the transtensional segment characterized by weak activity，serving as favorable parts for the development of dissolution vugs. The transpressional segment of the Middle Ordovician Yijianfang Formation exhibits a high linear density of fractures，while those of the Middle Ordovician Yijianfang Formation to the Middle-Lower Ordovician Yingshan Formation show a significantly decreased linear density of fractures vertically，leading to a limited dissolution capacity. The transtensional segment in the Middle Ordovician Yijianfang Formation has a moderate linear density of fractures，and those of the Middle Ordovician Yijianfang Formation to the Middle-Lower Ordovician Yingshan Formation exhibit well-developed fractures and dissolution vugs with an elevated number and scale，establishing this interval as a favorable area for reservoir development. © 2024 Editorial Department of Oil and Gas Geology. All rights reserved.

引用

页码：770 / 786

页数：16

共 77 条

[1]

QI Lixin, LI Zongjie, Et al., Tectonic sedimentary evolution and oil and gas exploration in the Tarim superimposed basin［M］, (2020)

[2]

KANG Yuzhu, Great hydrocarbon potential in the Paleozoic marine sequences in China［J］, Oil & Gas Geology, 31, 6, pp. 699-706, (2010)

[3]

Duan WEI, GAO Zhiqian, YANG Xiaoqun, Et al., Identification methods and features of unconformity within carbonate successions of the Lower-Middle Ordovician Yingshan Formation in Tahe area，Tarim Basin［J］, Journal of Palaeogeography, 19, 3, pp. 457-468, (2017)

[4]

ZHANG Changjian, MA Hailong, Et al., Fracture-cave system in collapsed underground paleo-river with subterranean flow in karst canyon area，Tahe oilfield［J］, Xinjiang Petroleum Geology, 44, 1, pp. 9-17, (2023)

[5]

LI Yuan, LU Xinbian, WANG Yingying, Et al., Hydrogeomorphologic characterization and evolution of the Early Hercynian karstification in Tahe Oilfield，the Tarim Basin［J］, Oil & Gas Geology, 37, 5, pp. 674-683, (2016)

[6]

WANG Yan, GAO Jiyuan, YANG Debin, Et al., Development conditions and geological models of large dendritic karst conduit in early Hercynian：A case study of B94 well block of Tahe Oilfield，Tarim Basin［J］, Fault-Block Oil and Gas Field, 30, 5, pp. 758-769, (2023)

[7]

LYU Yanping, JIANG Yingbing, GAO Jiyuan, Et al., The division of the Ordovician paleokarst small watershed in the west of Tahe and its geological significance［J］, Fault-Block Oil and Gas Field, 28, 4, pp. 440-445, (2021)

[8]

ZHANG San, JIN Qiang, QIAO Zhen, Et al., Differential tectonic evolution of the Ordovician and its significance in petroleum geology in main area of Tahe Oilfield［J］, Journal of China University of Mining & Technology, 49, 3, pp. 576-586, (2020)

[9]

XU Zhongxiang, MA Qingyou, Zonal differential deformation and reservoir control model of Ordovician strike-slip fault zone in Tahe Oilfield［J］, Marine Origin Petroleum Geology, 27, 2, pp. 124-134, (2022)

[10]

HU Wenge, Paleokarst fracture-vug types and their reconstruction in buried hill area，Tahe Oilfield，Tarim Basin［J］, Oil & Gas Geology, 43, 1, pp. 43-53, (2022)

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