Fracture Effectiveness and its Influence on Gas Productivity in Ultra‐deep Tight Sandstone Reservoirs of the Keshen Gas Field, Tarim Basin

Fracture effectiveness plays a key role in gas productivity of ultra‐deep tight sandstone reservoirs, Kuqa depression, Tarim Basin. Based on cores, thin sections, well logging, well testing and production data, the study evaluated fracture effectiveness and illustrated its impacts on gas productivit...

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Published in:Acta geologica Sinica (Beijing) 2024-12, Vol.98 (6), p.1557-1573
Main Authors: XU, Xiaotong, ZENG, Lianbo, DONG, Shaoqun, DIWU, Pengxiang, LI, Haiming, LIU, Jianzhong, HAN, Gaosong, XU, Hui, JI, Chunqiu
Format: Article
Language:English
Subjects:
Acidification
Apertures
Calcite
Compression
Compressive properties
Data logging
Diagenesis
Effectiveness
fracture effectiveness
Fracture surfaces
gas productivity
Geologic depressions
Gypsum
Kuqa depression
Logging
Membrane permeability
Normal stress
Oil and gas fields
Overpressure
Permeability
Pore pressure
Productivity
Reservoirs
Sandstone
Sedimentary rocks
tectonic fracture
Test wells
ultra‐deep tight sandstone
Vertical distribution
Vertical shear
Well logging
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Summary:Fracture effectiveness plays a key role in gas productivity of ultra‐deep tight sandstone reservoirs, Kuqa depression, Tarim Basin. Based on cores, thin sections, well logging, well testing and production data, the study evaluated fracture effectiveness and illustrated its impacts on gas productivity. High‐angle and vertical shear fractures are the most important types. Distribution of effective fractures shows great heterogeneous. Fracture effectiveness is influenced by tectonism, diagenesis and in‐situ stress. Earlier fractures or fractures in close to gypsum rock are easier to be filled. Completely filled fractures can be reopened under late tectonism. Dissolution improves local fracture effectiveness. Minerals spanning fracture surfaces protect fracture effectiveness from late compression. Fractures filled with calcite can be activated by acidification. Effective fractures parallel to maximum horizontal principal compressive stress direction show larger aperture. Overpressure can decrease the effective normal stress to maintain fracture effectiveness. With exploitation, decline in pore pressure reduces fracture effectiveness. Linear density, aperture, and strike of effective fractures influence gas productivity. Effective fractures greatly enhance matrix permeability. Therefore, more abundant and larger aperture fractures are always corresponded to higher productivity. However, effective fractures also facilitate late water invasion, especially, both mutually parallel. Intense water invasion leads to rapidly declines in productivity.
ISSN:1000-9515
1755-6724
DOI:10.1111/1755-6724.15259