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Salt-influenced normal faulting related to salt-dissolution and extensional tectonics: 3D seismic analysis and 2D numerical modeling of the Salt Valley salt wall, Utah and Danish Central Graben, North Sea
Naqi, Mohammad
Naqi, Mohammad
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2017
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Abstract
The northeastern Paradox basin is characterized by a series of salt cored anticlines (salt walls) trending NW-SE. The crestal areas of the salt cored anticlines are breached and cut by faults, forming downthrown valleys, created by the subsidence of the crestal overburden. There has been a prolonged debate on the causative mechanism of subsidence of the anticline crests. Some researchers, based on field observations favor salt-dissolution of the salt forming the core of the anticlines as the main mechanism for the crestal subsidence. Others based on physical modeling favor extensional tectonics as the main mechanism that triggered subsidence. A wider variety of salt structural styles are present in the Danish Salt Dome Province of the Danish Central Graben, ranging from salt diapirs that penetrate their overlying sedimentary cover, to gentle, non-penetrating salt-cored anticlines. Salt structures present as pillows (e.g. the Kraka salt pillow), diapirs (e.g. Skjold salt structure) and wall-and-sill complexes (e.g. Dan salt structure). The mechanism for the development of supra-salt faults above salt structures in the Danish Central Graben, North Sea is related to pure extensional tectonics that took place in Late Jurassic. A 3D seismic data volume covering the northern end of Salt Valley Salt Wall in the northeastern part of the Paradox Basin presents a unique opportunity to investigate and provide a new perspective on the origin of collapse structures. In addition, a 3D seismic covering the Danish Central Graben was utilized to analyze the supra-salt faults. The analysis of the supra-faults in the Danish Salt Province was performed in order to compare/contrast with supra-salt faults in the Paradox Basin. Interpretation of the Salt Valley seismic data shows a graben system that formed in the crestal area of the salt anticline. The graben system has a maximum displacement in the NW and decreases to the SE. The maximum displacement occurs where the salt crest is at deeper level and the minimum displacement, where the salt crest is higher. The data suggest that displacement on the graben system might be attributed to salt migration within the salt wall from where the overburden is thickest (higher head pressure) toward the SE of the salt wall where available seismic data suggest the overburden is thinnest. However, extensional fractures might also help in increasing the groundwater circulations in the areas where the salt anticline is closer to the surface. This might have enhanced salt dissolution in those areas triggering salt to flow from deeper parts along the strike of the salt wall. Several 2D numerical forward modeling was performed to test the hypothesis of salt-dissolution/withdrawal and extensional tectonics. This study suggests that the mechanism for the formation of the salt valleys might be attributed to extensional forces, salt dissolution and internal salt internal withdrawal rather that favoring a single mechanism for the formation of the salt valleys in the northeastern Paradox Basin. Also, fault analysis results obtained in this study reveal a slight distinction between the salt-dissolution normal faults and tectonic extensional normal faults. The dmax/L ratio of the salt-dissolution normal faults are slightly higher than the expected values based on the global fault database.
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