Q921 log lec5 v1
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The document provides an overview of spontaneous potential (SP) well logging. It discusses the origins and mechanisms of SP, including the liquid junction potential generated at interfaces between solutions of different salinities and the membrane potential caused by cation selectivity of shales. SP can be used to identify permeable zones and determine formation water resistivity. The largest SP deflections occur when there is a difference in salinity between the mud filtrate and formation water. The document includes examples of SP responses over different geological formations.
![Other applications of SP log
The SP is also used to indicate the amount of clay in a
reservoir.
The presence of clay coating the grains and throats of the
formation will impede the mobility of the Cl anions
because of the negative surface charge, and
thus spoil the development of the liquid-junction potential.
The ideal SP generated opposite a shaley sand when no
current flows is known as the pseudo static potential (PSP).
In addition to these quantitative interpretations,
elaborate connections have been established
between the shape of the SP over depth and
geologically significant events.
Some examples of using the SP curve to determine patterns
of sedimentation are given in Pirson [10].
Fall 13 H. AlamiNia
Well Logging Course:
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Q921 log lec5 v1
- 1. Well Logging Course (1st Ed.)
- 2. 1. Reading A Log 2. Examples of Curve Behavior And Log Display 3. Electrical Properties Of Rocks And Brines
- 3. 1. Spontaneous Potential A. membrane potential B. Application C. Log Example of The SP
- 5. Spontaneous potential Spontaneous potential main usage: the identification of permeable zones The origins of the spontaneous potential in wellbores involve both electrochemical potentials and the cation selectivity of shales. basis for the spontaneous potential is the process of diffusion –the self-diffusion of the dissolved ions in the fluids • in the borehole and in the formation. Fall 13 H. AlamiNia Well Logging Course: 5
- 6. The mechanism of generating the liquid-junction potential Electrochemical potentials of interest to the generation of the spontaneous potential are the liquid junction potential the membrane potential Figure schematically illustrates the situation for the generation of the liquid-junction potential. To the left is a saline solution of low NaCl concentration. To the right is one of a higher ionic concentration. Fall 13 H. AlamiNia Well Logging Course: 6
- 7. The liquid junction potential As is often the case, the resistivity of the drilling mud filtrate (Rmf ) is greater than the resistivity of the formation water (Rw), so: Where Vl−j is The liquid junction potential Fall 13 H. AlamiNia Well Logging Course: 7
- 8. A schematic representation of the development of the SP in a borehole The cell marked Ed corresponds to the liquid junction potential just discussed is sketched with the polarity corresponding to a higher electrolyte concentration in the formation water than in the mud filtrate. additional source of SP is associated with the shale result of the membrane potential generated in the presence of the shale that contains clay minerals which have large negative surface charge Fall 13 H. AlamiNia Well Logging Course: 8
- 10. A representation of a shale On the left, consisting of rock mineral grains and small platy clay particles. On the right the distributions of ions close to the face of one of the clay minerals is shown, which illustrates the so-called electrical double-layer. Fall 13 H. AlamiNia Well Logging Course: 10
- 11. How does a cation differ from an anion? A cation (s)(+) is a positively (+) charged ion. It loses one or more negatively charged electrons when forming ionic compounds. (are) almost always metals An anion (s) (-) is a negatively (-) charged ion. It gains one or more electrons when forming ionic compounds. (are) typically nonmetals Every ionic compound must contain both a cation and an anion so that the compound as a whole has no charge. A common example: In the ionic compound table salt (NaCl), sodium (Na+) is the cation, and chloride (Cl-) is the anion. Fall 13 H. AlamiNia Well Logging Course: 11
- 12. electrical double layer We assume that shale is nearly impermeable to fluid flow, but still capable of ionic transport, although considerably altered by the presence of clay minerals. The shale acts like a cation-selective (+) membrane. This property is related to the sheet-like structure of the alumino-silicates that form the basic structure of clay minerals. At the surface of the clay minerals there is a strong negative charge related to unpaired Si and O bonds. When the clay mineral particles are exposed to an ionic solution, one containing Na+ and Cl− for example, • the anions (Cl-) will be repulsed by their surfaces while the cations (Na+) will be attracted to the surface charge, forming the so-called electrical double layer. Fall 13 H. AlamiNia Well Logging Course: 12
- 13. membrane potential Close to the clay layers, the fluid will be dominated by cations since the anions are excluded by electrostatic repulsion. In this manner, in a complex mixture of clay minerals and other small mineral particles, with pore spaces even too small to permit the hydraulic flow of water, the cations will be able to diffuse along the charged surfaces, from high concentration to low concentration while the negative Cl ions will tend to be excluded. Such a diffusion process will tend to accumulate a positive charge on the low ionic concentration side of the shale barrier, producing an attendant electric field. In the practical situation, the cations from the fluid saturating the porous sand zone diffuse through the shale to the borehole with the lower cation concentration. Fall 13 H. AlamiNia Well Logging Course: 13
- 14. evaluating the membrane potential In this figure a semipermeable shale barrier separates the solutions of two different salinities. A schematic representation of the mechanism responsible for the generation of the membrane potential. The diffusion process is altered by the selective passage of Na+ through the shale membrane. Fall 13 H. AlamiNia Well Logging Course: 14
- 15. magnitude of the membrane potential The natural diffusion process is impeded because of the negative surface charge of the shale. The Cl ions which otherwise would diffuse more readily are prevented from traversing the shale membrane, whereas the less mobile Na ions can pass through it readily. The result is that the effective mobility of the chlorine in this case is reduced to nearly zero. magnitude of the membrane potential Vm Fall 13 H. AlamiNia Well Logging Course: 15
- 17. SP Measurement In the case of lower NaCl concentration in the mud, the voltages add, resulting in a more negative voltage in front of the sand than in front of the shale zone. The membrane potential provides about 4/5 of the SP amplitude, since the absolute value of mobilities enters in its potential, rather than the difference as in the liquid-junction potential. The SP is measured, between an electrode in the borehole and a distant reference. Fall 13 H. AlamiNia Well Logging Course: 17
- 18. natural potential vs. static spontaneous potential The shale baseline represents the natural potential between the two electrodes, without electrochemical effects, and is ideally a straight line from top to bottom. The static spontaneous potential (SSP), is the ideal SP generated by electrochemical effects when passing from the shale to a thick porous clean (shale-free) sand if no current flowed. Fall 13 H. AlamiNia Well Logging Course: 18
- 19. potential drop In practice the electrode can only measure the potential change in the borehole. Although the mud is usually less resistive than the formation, the area for current flow is much smaller in the borehole than in the formation, so that the borehole resistance is usually much higher than the formation resistance. Most of the potential drop therefore takes place in the borehole with the result that the measured SP amplitude in the center of the bed is close to the SSP. Fall 13 H. AlamiNia Well Logging Course: 19
- 20. The determination of Rw In the best of cases, the measurement of the SP allows the identification of permeable zones and the determination of formation water resistivity. Since the mud filtrate resistivity can be measured, the formation water resistivity can be calculated using factors that are well known for NaCl solutions. A deflection indicates that a zone is porous and permeable and has water with a different ionic concentration than the mud. Fall 13 H. AlamiNia Well Logging Course: 20
- 21. effective water resistivities vs. actual resistivities In practice the electrochemical potential is often written in terms of effective water resistivities (Rmf e) and (Rwe) rather than actual resistivities. These are equal to Rmf and Rw except for concentrated or dilute solutions. In concentrated solutions, below about 0.1 ohm- m at 75◦ F, the conductivity is no longer proportional to the number density of charge carriers and their mobilities. • At high concentrations the proximity of the ions to one another is increased; their mutual attractions begin to compete with the solvation to reduce their mobilities. In dilute solutions of most oilfield waters, other ions than Na+ Cl− become increasingly important. Numerous charts exist for the determination of Rw from the SP, knowing Rmf and temperature. Fall 13 H. AlamiNia Well Logging Course: 21
- 22. Other applications of SP log The SP is also used to indicate the amount of clay in a reservoir. The presence of clay coating the grains and throats of the formation will impede the mobility of the Cl anions because of the negative surface charge, and thus spoil the development of the liquid-junction potential. The ideal SP generated opposite a shaley sand when no current flows is known as the pseudo static potential (PSP). In addition to these quantitative interpretations, elaborate connections have been established between the shape of the SP over depth and geologically significant events. Some examples of using the SP curve to determine patterns of sedimentation are given in Pirson [10]. Fall 13 H. AlamiNia Well Logging Course: 22
- 25. SP vs. other logging techniques The measurement of the SP is probably the antithesis of the high-tech image of many of the other logging techniques. The sensor is simply an electrode (often mounted on an insulated cable, known as the “bridle,” some tens of feet above any other measurement sondes) which is referenced to ground at the surface. The measurement is essentially a dc voltage measurement in which it is assumed that unwanted sources of dc voltage are constant or only slowly varying with time and depth. Fall 13 H. AlamiNia Well Logging Course: 25
- 26. shale and clean sand beds along with the idealized response of SP logging deflections to the left correspond to increasingly negative values. In the first sand zone, there is no SP deflection since this case represents equal salinity in the formation water and in the mud filtrate. The next two zones show a development of the SP which is largest for the largest contrast in mud filtrate and formation water resistivity. In the last zone, the deflection is seen to be to the right of the shale baseline and corresponds to the case of a mud filtrate which is saltier than the original formation fluid. Fall 13 H. AlamiNia Well Logging Course: 26
- 27. several cases of SP log for a given contrast in Rmf & Rw It illustrates several cases, for a given contrast in mud filtrate salinity and formation water salinity, where the SP deflection will not attain the full value seen in a thick, clean sand. The first point is that the deflection will be reduced if the sand bed is not thick enough because not enough of the potential drop occurs in the borehole. The transition at the bed boundary is much slower for the same reason. Depending mainly on the depth of invasion and the contrast between invaded zone and mud resistivity, the bed thickness needs to be more than 20 times the borehole diameter to attain its full value. Fall 13 H. AlamiNia Well Logging Course: 27
- 28. several cases of SP log for a given contrast in Rmf & Rw The second point is the effect of clay in reducing the SP. The third point is the effect of oil or gas. In a clean sand the electrochemical potentials are not affected by oil or gas, but the formation resistivities are higher so that the transition at bed boundaries may be slower and a thicker bed may be needed for full SP development. However, the effect of oil or gas is stronger in a shaley sand. The electrochemical potentials are reduced compared to a water-bearing sand because there is less water in the pore space, so that the effect of the surface-charged clay particles is proportionately higher. Fall 13 H. AlamiNia Well Logging Course: 28
- 29. Other effects which can also upset the SP electrical noise, and bimetallic currents between the different metal parts of a logging tool that can create an unwanted potential at the SP electrode. the electrokinetic, or streaming, potential caused by the higher pressure in the borehole moving cations through a cation-selective membrane. The membrane may be a shale that has some very small permeability (Esh 3.8), or the mudcake which contains a large percentage of clay particles and also has some very small permeability (Emc). Fall 13 H. AlamiNia Well Logging Course: 29
- 30. Other effects which can also upset the SP (Cont.) Normally these effects are small and balance each other out. However, when the pressure differential is high, or the mud and other resistivities are high enough that even a small current produces a large potential, the electrokinetic effect can be comparable to the electrochemical effect. The baseline often drifts slowly with time and depth. Sharper shifts occur when the membrane potential at the top of a sand is different to that at the bottom. This happens when the top and bottom shales have different cation selection properties, and also when the formation water or hydrocarbon saturation changes within the sand. Fall 13 H. AlamiNia Well Logging Course: 30
- 31. summary SP curve behavior under a variety of logging circumstances Finally, the symmetric responses of SP logs can be upset by vertical movement of mud filtrate in high permeability sands: upwards in the presence of heavier saline formation water, and downwards in the presence of gas and light oil. Fall 13 H. AlamiNia Well Logging Course: 31
- 32. 1. Ellis, Darwin V., and Julian M. Singer, eds. Well logging for earth scientists. Springer, 2007. Chapter 3