Application of Fluid Inclusion Analysis for Buried Dissolution Predicting in the Tahe Oilfield of Tarim Basin, NW China

This study was undertaken to establish an evaluation method for buried dissolution of carbonate reservoir in the Tahe (塔河) Oilfield. Because of the difficulty in tracing the dissolution in geologic record, the precipitation is taken as a useful indicator to presume the dissolution reversed. The flui...

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Bibliographic Details
Published inJournal of earth science (Wuhan, China) Vol. 24; no. 3; pp. 343 - 354
Main Author 阮壮 于炳松 陈圆圆
Format Journal Article
LanguageEnglish
Published China University of Geosciences China University of Geosciences 01.06.2013
Springer Nature B.V
Subjects
Basins
Biogeosciences
Calcite
Caves
Earth and Environmental Science
Earth science
Earth Sciences
Fluid dynamics
Geochemistry
Geology
Geotechnical Engineering & Applied Earth Sciences
Oil and gas exploration
Oil and gas fields
Ordovician
中国
体分析
埋地
塔河油田
塔里木盆地
流体包裹体
溶解
降水趋势
China
Tarim Basin
carbonate rock
buried dissolution
Gibbs free energy
fluid inclusion
Tarim Basin
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Summary:This study was undertaken to establish an evaluation method for buried dissolution of carbonate reservoir in the Tahe (塔河) Oilfield. Because of the difficulty in tracing the dissolution in geologic record, the precipitation is taken as a useful indicator to presume the dissolution reversed. The fluid inclusions data is a useful tool to identify the precipitation. On the basis of the principle that the temperature data of fluid inclusions captured in the calcite fillings of caves and cracks can reflect the fluid activity time, a total of 256 fluid inclusions samples in 12 drills were collected and analyzed to study their forming time in buried environment in the Tahe Oilfield, Tarim Basin, NW China. Results show that the temperature data of fluid inclusions captured by Ordovician cave and crack fillings accumulated in six intervals, which indicated six stages of fluid activity in the area of study. Meanwhile, it is clear that a different number of temperature intervals was captured in different wells, representing a different number of precipitation distributed in space. According to this conclusion, the buried precipitation trend in late Himalayan stage (the sixth stage) was supposed in space and its effectiveness has been approved by the chemical thermodynamics method. This method was also used in all of the other five stages of fluid activity and the comprehensive trend of the buried precipitation in space for Ordovician strata was evaluated. It shows that more temperature intervals were captured in the southwestern region (wells S76, S79, S65 and S75) and the eastern region (well S69) in the area of study, indicating intensive precipitation and weak dissolution in this area. This evaluation method for buried dissolution is a new attempt and may have important implications for further petroleum exploration in the Tarim Basin.
Bibliography:carbonate rock;buried dissolution;fluid inclusion;Gibbs free energy;Tarim Basin.
Zhuang Ruan*, Bingsong Yu, Yuanyuan Chen State Key Laboratory of Geological Processes and Mineral Resources, China University of Geosciences, Beijing 100083, China
42-1788/P
This study was undertaken to establish an evaluation method for buried dissolution of carbonate reservoir in the Tahe (塔河) Oilfield. Because of the difficulty in tracing the dissolution in geologic record, the precipitation is taken as a useful indicator to presume the dissolution reversed. The fluid inclusions data is a useful tool to identify the precipitation. On the basis of the principle that the temperature data of fluid inclusions captured in the calcite fillings of caves and cracks can reflect the fluid activity time, a total of 256 fluid inclusions samples in 12 drills were collected and analyzed to study their forming time in buried environment in the Tahe Oilfield, Tarim Basin, NW China. Results show that the temperature data of fluid inclusions captured by Ordovician cave and crack fillings accumulated in six intervals, which indicated six stages of fluid activity in the area of study. Meanwhile, it is clear that a different number of temperature intervals was captured in different wells, representing a different number of precipitation distributed in space. According to this conclusion, the buried precipitation trend in late Himalayan stage (the sixth stage) was supposed in space and its effectiveness has been approved by the chemical thermodynamics method. This method was also used in all of the other five stages of fluid activity and the comprehensive trend of the buried precipitation in space for Ordovician strata was evaluated. It shows that more temperature intervals were captured in the southwestern region (wells S76, S79, S65 and S75) and the eastern region (well S69) in the area of study, indicating intensive precipitation and weak dissolution in this area. This evaluation method for buried dissolution is a new attempt and may have important implications for further petroleum exploration in the Tarim Basin.
ISSN:1674-487X
1867-111X
DOI:10.1007/s12583-013-0338-x