Bedding-parallel fractures in ultradeep tight sandstone reservoirs in Jurassic and Cretaceous of Yongjin Oil Field, Junggar Basin, China

Bedding-parallel fractures are fractures that are parallel to rock bedding structure planes and have been widely accepted as a key factor for oil and gas production in tight sandstone and shale reservoirs. However, the formation mechanisms of these parallel-bedding fractures are still under debate....

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Bibliographic Details
Published in:Frontiers of earth science 2022-12, Vol.16 (4), p.975-988
Main Authors: LIU, Hongping, ZHANG, Changmin, ZHANG, Li, LUO, Yang
Format: Article
Language:English
Subjects:
Bedding
Bedding structures
Bedding-parallel fractures
Bitumen
Carbonates
Cementation
Compression
Core drilling
Coring
Cretaceous
Drilling
Earth and Environmental Science
Earth Sciences
fracture origin
Fractures
Gas production
Geochemistry
Junggar Basin
Jurassic
Mechanical properties
Oil
Oil and gas fields
Oil and gas production
Oil fields
Overburden
Overpressure
Oxygen
Oxygen isotopes
Pore pressure
Pore water pressure
Research Article
Reservoirs
Rocks
Sandstone
Sedimentary rocks
Shale
Shale gas
Tectonics
Tensile strength
tight sandstone
ultradeep reservoirs
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Summary:Bedding-parallel fractures are fractures that are parallel to rock bedding structure planes and have been widely accepted as a key factor for oil and gas production in tight sandstone and shale reservoirs. However, the formation mechanisms of these parallel-bedding fractures are still under debate. In this study, bedding-parallel fractures in Yongjin Oil Field were analyzed using methods including core and microscopic observations, element geochemistry, and carbon and oxygen isotope analysis. Their origin and relations to reservoir quality, faults, and rock mechanical properties were examined. The discovery of bedding-parallel fractures in both the Upper Jurassic and Lower Cretaceous formations indicates that the BPFs are generated later than the early Cretaceous. The filling state of bedding-parallel fractures that with no bitumen and carbonate cement indicate that they formed after oil charging and carbonate cementation. The tensile fracture characteristics in core and thin section observations, and the fact that overburden stress exceeds the pore pressure indicate that the bedding-parallel fractures were neither generated from tectonic compression nor overpressure. The most likely generation mechanism is stress relief during core drilling under high in situ stress conditions. High in situ stress and low tensile strength lead to thinner fracture spacing. The existence of high bedding-parallel fracture density is an indicator of good reservoir quality and result in high oil/gas production.
ISSN:2095-0195
2095-0209
DOI:10.1007/s11707-022-0999-9