Mapping the resistivity structure of Walker Ridge 313 in the Gulf of Mexico using the marine CSEM method

Karen Weitemeyer; Steven Constable; Dianna Shelander; Seth S. Haines

doi:10.1016/j.marpetgeo.2017.08.039

Mapping the resistivity structure of Walker Ridge 313 in the Gulf of Mexico using the marine CSEM method

Marine and Petroleum Geology

By: Karen Weitemeyer, Steven Constable, Dianna Shelander, and Seth S. Haines

https://doi.org/10.1016/j.marpetgeo.2017.08.039

Metrics

14

Crossref references

Web analytics dashboard Metrics definitions

Links

More information: Publisher Index Page (via DOI)
Open Access Version: Publisher Index Page
Download citation as: RIS | Dublin Core

Abstract

A marine controlled source electromagnetic (CSEM) campaign was carried out in the Gulf of Mexico to further develop marine electromagnetic techniques in order to aid the detection and mapping of gas hydrate deposits. Marine CSEM methods are used to obtain an electrical resistivity structure of the subsurface which can indicate the type of substance filling the pore space, such as gas hydrates which are more resistive. Results from the Walker Ridge 313 study (WR 313) are presented in this paper and compared with the Gulf of Mexico Gas Hydrate Joint Industry Project II (JIP2) logging while drilling (LWD) results and available seismic data. The hydrate, known to exist within sheeted sand deposits, is mapped as a resistive region in the two dimensional (2D) CSEM inversion models. This is consistent with the JIP2 LWD resistivity results. CSEM inversions that use seismic horizons provide more realistic results compared to the unconstrained inversions by providing sharp boundaries and architectural control on the location of the resistive and conductive regions in the CSEM model. The seismic horizons include: 1) the base of the gas hydrate stability zone (BGHSZ), 2) the top of salt, and 3) the top and bottom of a fine grained marine mud interval with near vertical hydrate filled fractures, to constrain the CSEM inversion model. The top of salt provides improved location for brines, water saturated salt, and resistive salt. Inversions of the CSEM data map the occurrence of a ‘halo’ of conductive brines above salt. The use of the BGHSZ as a constraint on the inversion helps distinguish between free gas and gas hydrate as well as gas hydrate and water saturated sediments.

Suggested Citation

Weitemeyer, K., Constable, S., Shelander, D., Haines, S.S., 2024, Mapping the resistivity structure of Walker Ridge 313 in the Gulf of Mexico using the marine CSEM method: Marine and Petroleum Geology, v. 88, p. 1013-1031, https://doi.org/10.1016/j.marpetgeo.2017.08.039.

Study Area

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Mapping the resistivity structure of Walker Ridge 313 in the Gulf of Mexico using the marine CSEM method
Series title	Marine and Petroleum Geology
DOI	10.1016/j.marpetgeo.2017.08.039
Volume	88
Year Published	2024
Language	English
Publisher	Elsevier
Contributing office(s)	Central Energy Resources Science Center
Description	19 p.
First page	1013
Last page	1031
Country	United States
State	Louisiana
City	Houma
Other Geospatial	Gulf of Mexico, Walker Ridge 313