Ten years of marine CSEM for hydrocarbon exploration

Constable, Steven

doi:10.1190/1.3483451

Cited by 486 publications

(233 citation statements)

References 68 publications

(40 reference statements)

Supporting

Mentioning

227

Contrasting

Unclassified

Order By: Relevance

“…Controlled Source electromagnetic (CSEM) prospecting has become an established tool for a wide range of exploration targets, including marine (Constable 2010), airborne (Siemon et al 2009) and cross well applications (Newman & Alumbaugh 1997). Despite all improvements during the last decade, the presence of steel-cased wells in the study area remains a challenging task for EM modelling methodologies.…”

Section: Introductionmentioning

confidence: 99%

Steel-cased wells in 3-D controlled source EM modelling

Patzer

Tietze²,

Ritter

2017

Geophysical Journal International

View full text Add to dashboard Cite

S U M M A R YOver the last decades, electromagnetic methods have become an accepted tool for a wide range of geophysical exploration purposes and nowadays even for monitoring. Application to hydrocarbon monitoring, for example for enhanced oil recovery, is hampered by steelcased wells, which typically exist in large numbers in producing oil fields and which distort electromagnetic fields in the subsurface. Steel casings have complex geometries as they are very thin but vertically extended; moreover, the conductivity contrast of steel to natural materials is in the range of six orders of magnitude. It is therefore computationally prohibitively costly to include such structures directly into the modelling grid, even for finite element methods. To tackle the problem we developed a method to describe steel-cased wells as series of substitute dipole sources, which effectively interact with the primary field. The new approach cannot only handle a single steel-cased well, but also an arbitrary number, and their interaction with each other. We illustrate the metal casing effect with synthetic 3-D modelling of land-based controlled source electromagnetic data. Steel casings distort electromagnetic fields even for large borehole-transmitter distances above 2 km. The effect depends not only on the distance between casing and transmitter, but also on the orientation of the transmitter to the borehole. Finally, we demonstrate how the presence of steel-cased wells can be exploited to increase the sensitivity and enhance resolution in the target region. Our results show that it is at least advisable to consider the distribution of steel-cased wells already at the planning phase of a controlled source electromagnetic field campaign.

show abstract

Section: Introductionmentioning

confidence: 99%

Steel-cased wells in 3-D controlled source EM modelling

Patzer

Tietze²,

Ritter

2017

Geophysical Journal International

View full text Add to dashboard Cite

show abstract

“…What is generally observed, by geophysical methods or direct observations, in sediment cores, is the depth of ice-bonded permafrost (IBP) below the sea floor (which is equivalent to the thickness of the overlying unfrozen sediment). Direct current resistivity and controlled source electromagnetic techniques for the investigation of submarine permafrost have been established in a number of studies (Barnes, 1963;Constable, 2010;Corwin, 1983;Sellmann et al, 1989). Laboratory measurements of the bulk electrical properties of frozen porous media show the effect of ice content and thus saline porewater on electrical resistivity .…”

Section: Introductionmentioning

confidence: 99%

Coastal dynamics and submarine permafrost in shallow water of the central Laptev Sea, East Siberia

et al. 2016

View full text Add to dashboard Cite

Abstract. Coastal erosion and flooding transform terrestrial landscapes into marine environments. In the Arctic, these processes inundate terrestrial permafrost with seawater and create submarine permafrost. Permafrost begins to warm under marine conditions, which can destabilize the sea floor and may release greenhouse gases. We report on the transition of terrestrial to submarine permafrost at a site where the timing of inundation can be inferred from the rate of coastline retreat. On Muostakh Island in the central Laptev Sea, East Siberia, changes in annual coastline position have been measured for decades and vary highly spatially. We hypothesize that these rates are inversely related to the inclination of the upper surface of submarine ice-bonded permafrost (IBP) based on the consequent duration of inundation with increasing distance from the shoreline. We compared rapidly eroding and stable coastal sections of Muostakh Island and find permafrost-table inclinations, determined using direct current resistivity, of 1 and 5 %, respectively. Determinations of submarine IBP depth from a drilling transect in the early 1980s were compared to resistivity profiles from 2011. Based on borehole observations, the thickness of unfrozen sediment overlying the IBP increased from 0 to 14 m below sea level with increasing distance from the shoreline. The geoelectrical profiles showed thickening of the unfrozen sediment overlying ice-bonded permafrost over the 28 years since drilling took place. We use geoelectrical estimates of IBP depth to estimate permafrost degradation rates since inundation. Degradation rates decreased from over 0.4 m a −1 following inundation to around 0.1 m a −1 at the latest after 60 to 110 years and remained constant at this level as the duration of inundation increased to 250 years. We suggest that long-term rates are lower than these values, as the depth to the IBP increases and thermal and porewater solute concentration gradients over depth decrease. For the study region, recent increases in coastal erosion rate and changes in benthic temperature and salinity regimes are expected to affect the depth to submarine permafrost, leading to coastal regions with shallower IBP.

show abstract

“…Consequently, the marine controlled-source electromagnetic (CSEM) technique (Constable et al 1998;Constable 2006;Key 2012) was modified to use higher transmitted frequencies and a fixed offset three-axis electric field receiver, to extend the CSEM capability to detect shallow and subtle resistivity anomalies with high resolution (Weitemeyer & Constable 2010). CSEM sounding is highly sensitive to volumetric changes in resistivity (Edwards 2005;Constable 2010), mainly related to pore fluid properties; therefore, it can detect robustly fluid migration pathways and quantify porosity (Harris & MacGregor 2006;MacGregor & Tomlinson 2014;Naif et al 2015).…”

Section: Marine Csem Surveymentioning

confidence: 99%

Controlled-source electromagnetic and seismic delineation of subseafloor fluid flow structures in a gas hydrate province, offshore Norway

et al. 2016

View full text Add to dashboard Cite

SUMMARYDeep sea pockmarks underlain by chimney-like or pipe structures that contain methane hydrate are abundant along the Norwegian continental margin. In such hydrate provinces the interaction between hydrate formation and fluid flow has significance for benthic ecosystems and possibly climate change. The Nyegga region, situated on the western Norwegian continental slope, is characterized by an extensive pockmark field known to accommodate substantial methane gas hydrate deposits. The aim of this study is to detect and delineate both the gas hydrate and free gas reservoirs at one of Nyegga's pockmarks.In 2012, a marine controlled-source electromagnetic (CSEM) survey was performed at a pockmark in this region, where high-resolution three-dimensional seismic data were previously collected in 2006. Two-dimensional CSEM inversions were computed using the data acquired by ocean bottom electrical field receivers. Our results, derived from un- constrained and seismically constrained CSEM inversions, suggest the presence of two distinctive resistivity anomalies beneath the pockmark: a shallow vertical anomaly at the underlying pipe structure, likely due to gas hydrate accumulation, and a laterally extensive anomaly attributed to a free gas zone below the base of the gas hydrate stability zone. This work contributes to a robust characterization of gas hydrate deposits within sub-seafloor fluid flow pipe structures.

show abstract

Ten years of marine CSEM for hydrocarbon exploration

Cited by 486 publications

References 68 publications

Steel-cased wells in 3-D controlled source EM modelling

Steel-cased wells in 3-D controlled source EM modelling

Coastal dynamics and submarine permafrost in shallow water of the central Laptev Sea, East Siberia

Controlled-source electromagnetic and seismic delineation of subseafloor fluid flow structures in a gas hydrate province, offshore Norway

Contact Info

Product

Resources

About