Recognition and evaluation of low-resistivity pay

Worthington, Paul F.

doi:10.1144/petgeo.6.1.77

Cited by 78 publications

(32 citation statements)

References 15 publications

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“…The results in this paper pertain to a 10:1 resistivity contrast. Lower contrasts are frequently observed, and can even be reversed in shaly sands or carbonate host formations (Worthington 2000), while contrasts of 100:1 are quite rare. In the presence of a higher resistivity contrast, the effect of the galvanic reservoir will be stronger for a given offset and water depth, and hence the transitions noted regarding the Poynting vector, Joule heating and electric field will move to longer offsets.…”

Section: Discussionmentioning

confidence: 98%

On the physics of frequency-domain controlled source electromagnetics in shallow water. 1: isotropic conductivity

Chave¹,

Everett

Mattsson³

et al. 2016

Geophys. J. Int.

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S U M M A R YIn recent years, marine controlled source electromagnetics (CSEM) has found increasing use in hydrocarbon exploration due to its ability to detect thin resistive zones beneath the seafloor. It is the purpose of this paper to evaluate the physics of CSEM for an ocean whose electrical thickness is comparable to or much thinner than that of the overburden using the in-line configuration through examination of the elliptically polarized seafloor electric field, the time-averaged energy flow depicted by the real part of the complex Poynting vector, energy dissipation through Joule heating and the Fréchet derivatives of the seafloor field with respect to the subseafloor conductivity that is assumed to be isotropic. The deep water (ocean layer electrically much thicker than the overburden) seafloor EM response for a model containing a resistive reservoir layer has a greater amplitude and reduced phase as a function of offset compared to that for a half-space, or a stronger and faster response. For an ocean whose electrical thickness is comparable to or much smaller than that of the overburden, the electric field displays a greater amplitude and reduced phase at small offsets, shifting to a stronger amplitude and increased phase at intermediate offsets and a weaker amplitude and enhanced phase at long offsets, or a stronger and faster response that first changes to stronger and slower, and then transitions to weaker and slower. These transitions can be understood by visualizing the energy flow throughout the structure caused by the competing influences of the dipole source and guided energy flow in the reservoir layer, and the air interaction caused by coupling of the entire subseafloor resistivity structure with the sea surface. A stronger and faster response occurs when guided energy flow is dominant, while a weaker and slower response occurs when the air interaction is dominant. However, at intermediate offsets for some models, the air interaction can partially or fully reverse the direction of energy flux in the reservoir layer toward rather than away from the source, resulting in a stronger and slower response. The Fréchet derivatives are dominated by preferential sensitivity to the reservoir layer conductivity for all water depths except at high frequencies, but also display a shift with offset from the galvanic to the inductive mode in the underburden and overburden due to the interplay of guided energy flow and the air interaction. This means that the sensitivity to the horizontal conductivity is almost as strong as to the vertical component in the shallow parts of the subsurface, and in fact is stronger than the vertical sensitivity deeper down. However, the sensitivity to horizontal conductivity is still weak compared to the vertical component within thin resistive regions. The horizontal sensitivity is gradually decreased when the water becomes deep. These observations in part explain the success of shallow towed CSEM using only measurements of the in-line component of the electric field.

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Section: Discussionmentioning

confidence: 98%

On the physics of frequency-domain controlled source electromagnetics in shallow water. 1: isotropic conductivity

Chave¹,

Everett

Mattsson³

et al. 2016

Geophys. J. Int.

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show abstract

“…Nevertheless, the protonic motion which is assumed to be responsible for the very poor conductivity observed in brucite type samples as Ni(OH) 2 and Mg(OH) 2 leads to higher activation energies of about 1 eV [30,31]. It is then realistic to assume that the dc conductivity of our clay samples is likely to result from the displacement of the cations located at the surface of the grain, i.e., the exchangeable cations.…”

Section: Conductivity Measurementsmentioning

confidence: 97%

“…Moreover, the possible effect of temperature on these properties has not been reported yet. According to Worthington [2], low resistivity in argillaceous sandstone reservoirs may be attributed either to the effect of microporosity or to specific effects due to clays and/or to conducting minerals. Effect of clays' CEC, such as smectite, illite, and kaolinite, on resistivity measurements of sandstones has been widely studied in the literature and has contributed in the building of well-known log interpretation models [3][4][5][6][7].…”

Section: Introductionmentioning

confidence: 99%

DC conductivity, cationic exchange capacity, and specific surface area related to chemical composition of pore lining chlorites

Henn

Durand

Cérepi

et al. 2007

Journal of Colloid and Interface Science

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“…Low-resistivity pay zones display a low-resistivity contrast between a brine-water-bearing section of the reservoir and a hydrocarbon-bearing (oil or gas) part of the reservoir (Worthington, 2000). Hamada et al (2000), subdivided the cause of low-resistivity pay zones into two main categories:…”

Section: Low-resistivity Paymentioning

confidence: 99%

“…The causes of low-resistivity are directed at specific reservoirs or particular depositional environments and may not be directly applicable to other reservoirs, where conditions initially appear to be similar (Worthington, 2000). It is therefore necessary to study and understand the specific causes of the low-resistivity pay in the J-and K-Reservoirs of the Mozambique basin and to recommend an algorithm and a workflow that can improve the accuracy of calculation of water saturation in these reservoirs.…”

Section: Low-resistivity Paymentioning

confidence: 99%

Calculation of water saturation in low resistivity gas reservoirs and pay-zones of the Cretaceous Grudja Formation, onshore Mozambique basin

Mashaba¹,

Altermann²

2015

Marine and Petroleum Geology

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Recognition and evaluation of low-resistivity pay

Cited by 78 publications

References 15 publications

On the physics of frequency-domain controlled source electromagnetics in shallow water. 1: isotropic conductivity

On the physics of frequency-domain controlled source electromagnetics in shallow water. 1: isotropic conductivity

DC conductivity, cationic exchange capacity, and specific surface area related to chemical composition of pore lining chlorites

Calculation of water saturation in low resistivity gas reservoirs and pay-zones of the Cretaceous Grudja Formation, onshore Mozambique basin

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