Abstract
The present work deals with an interpretation of well log data (gamma ray (GR), resistivity, density, and neutron) from four wells, namely P-1, P-2, P-3 and P-4 in the study area of the Rio Del Rey basin. The well logs analysis indicates five potential sandstone reservoirs at the P-1, two at the P-2, four at the P-3 and six at the P-4. The neutron–density-GR logs highlight the sandstone gas reservoir characterized by high resistivity and crossover between neutron density. The neutron–density-GR cross-plot confirms the presence of sandstone containing hydrocarbons by a displacement of the cloud of points, from low to medium GR values, from the sandstone line to the left. Petrophysical parameters exhibit the value 12–41% for a volume of shale, 15–34% for effective porosity, 29–278 mD for permeability and 3–63% for water saturation. The three potential hydrocarbon reservoir saturation ranges from 22 to 45%. The study will contribute to future offshore oil and gas exploration and development in the Rio Del Rey basin, based on the geological and geophysical characteristics of the reservoirs delineated.
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Introduction
Estimation of petrophysical properties such as porosity, permeability, the volume of shale, fluid saturation and thickness of reservoirs plays a vital role in the oil and gas industry (Kumar et al. 2016; Saadu and Nwankwo 2017). Well-logging data can accurately detect reservoir fluid volume and composition, if interpreted correctly and ideally calibrated to core data (Asquith et al. 2004; Darling 2005; Abudeif et al. 2016; Radwan 2018; Bai et al. 2019). Gas-bearing zones will show a greater separation in neutron–density crossover than oil zones, and oil can be inferred to be in places where low crossover magnitude is detected (Asquith et al. 2004; Schechter 2010). In Cameroon, two types of basins define the general sedimentary context formation. The intracontinental type located mostly between Mamfe and Lake Chad, and the coastal basins type, which run along the Cameroonian Atlantic coast and are part of the large set of basins on the West African coast. The two main coastal sedimentary basins, namely: the RDR, representing the southeastern extension of the Niger Delta and the Douala/Kribi-Campo Basin; a great epicontinental depression with a passive margin, resulting from the rifting of the South Atlantic. The volcanic line of Cameroon separates them (Societé National des Hydrocarbures 2005). The offshore part of the RDR basin represents one of Cameroon's main oil regions (Societé National des Hydrocarbures 2005). The RDR basin is therefore of major scientific and economic interest.
Numerous studies have been carried out by academic and legal entities (Oil Companies and others), in the RDR basin. These works have provided knowledge of this basin, both geologically and geodynamically. Coughlin et al. (1993) identified three structural provinces in the RDR and showed that the productive reservoirs are excellent and shallow, located within 2000 m. They are identified by good-quality bedrock corresponding to Paleocene-Eocene marine clays. Mvondo (2010) has shown from an analysis of the seismic data and well, a clear succession between two large sedimentary systems: the turbiditic channels of the Miocene and the delta of Miocene-real progression. Koum (2013) demonstrated the relative Plio-Pleistocene uplift of the southern coastal surface margin of the RDR thanks to the measurement of the river incision. This heightening is linked to the Pliocene activity of the Cameroon volcanic line and the numerous reactivations of post-Pan-African faults. Njoh and Agbor (2016) built environments in the basin by integrating paleontological, granulometric and petrographic data. Interpretation of these data involved major marine environments, medium neritic and then transitions between coastal and intertidal environments where there were deposits of Cretaceous sediments. Other works have been carried out in this basin but have remained unpublished, for example, that of, which concerned the production of a synthesis of old works carried over the basin. This unpublished internal report entitled “Kinematic, tectonic, sedimentary and petroleum synthesis of the RDR basin” presents ideas on the geology of the basin. In petrophysics, apart from the log studies carried out by oil companies, which are not very accessible, there are very few studies related to it. From this, it follows that the RDR basin is still less known from a petrophysical point of view. The best oil potential of the Rio Del Rey basin is found in its central part, unlike that of the Douala Basin. According to the National Hydrocarbon Company report, Cameroonian hydrocarbon production fell by 1.59% in April 2019 compared to 2018, during the same month. This drop-in production is mainly due to the depletion of fields. To remedy this deficit, the Cameroonian State has promoted several blocks in the Douala/Kribi-Campo basin and that of Rio Del Rey. Prospecting for these blocks begins with a better understanding of geological and petrophysical knowledge of neighboring or operating fields in the basin. A major query then arises concerning the quality of the source formations, reservoirs and covers of the Rio Del Rey basin. In this context, a study on the characterization of reservoirs in the Rio Del Rey basin is therefore beneficial.
The Rio Del Rey (RDR) basin is located at the edge of the Gulf of Guinea and belongs to the large group of basins of the West African Margin. According to Societé National des Hydrocarbures (2015), the offshore part of the RDR basin represents one of Cameroon’s oil regions. This study proposes to analyze log data from four oil wells P1, P2, P3 and P4 offshore of the southwest zone of the Rio Del Rey basin in order to highlight the characteristics of the reservoirs of the basin and consequently to evaluate the quality of the latter, through their petrophysical properties.
The Rio Del Rey basin setting
The study area located between latitude 4° and 5° North and longitude 8°20′ and 9°10′ East, the RDR basin (Fig. 1), is one of the coastal basins of the southwest region of Cameroon and represents the southeastern extension of the Niger Delta into the Gulf of Guinea (Coughlin et al. 1993). The RDR basin is bordered by Nigeria's Niger Delta Basin to the west and northwest, by the Rio Muni basin in Equatorial Guinea to the south, to the north by the Rumpi hills and to the east by the Cameroon Volcanic Line which separates the RDR basin from the Douala/Kribi-Campo basin (Coughlin et al. 1993). It covers an area of approximately 7000 km2 offshore, and at its central part, the sediments are estimated to be less than 12 km thick, but generally, this thickness is estimated at around 6 km (Doust 1990). The formation and tectonic evolution of this basin like all the other basins bordering the West African coast are closely linked to the rifting process which permitted the opening of the South Atlantic and the formation of the Gulf of Guinea, by the separation of African and South American continents during the Albo-Aptian (Rabinovich 1979). Sedimentation in the basin began during the Cretaceous, and the sequences are linked to sedimentation in the Benue trench, the Douala basin and other basins in southeast Nigeria (Nair 1981; Nguene 1992; Petters 1995; Njoh 2008, 2010). Three main diachronic formations, each corresponding to very specific environments, are encountered in this basin (Njoh and Agbor Taku 2016): (1) The Akata Formation of the Late Paleocene, formed of prodeltaic marine clay covering the sediments from the Cretaceous; (2) the recent Agbada Formation of the Oligocene–Miocene covering the Akata Formation and composed of a delta front with alternating sand and clay; (3) the Recent Pliocene superficial formation of Benin, made up of fluvial sands and sandstones from the coastal plains, clays of the Agbada, the Akata and those of the Cretaceous (Kita clay).
The RDR stratigraphy can be divided into two units: a Pre-Deltaic unit from the Paleocene to Miocene and a deltaic unit.
The Upper Paleocene was encountered in a well in the locality of Yaounde and has been clay identified. The Eocene series generally consist of clays deposited in a marine environment. A small amount of volcanic material may also be present in these series. An interesting turbiditic system has been discovered in deep water environments: the Ongue and Debunsha sands. A similar repository system continued to be developed during the Lower Miocene.
The deltaic sediments belong to the eastern extension of the Niger Delta. Overall, they form a sequence of prograding deposits deposited mainly during the late Miocene and early Pliocene. This sedimentation was made of alternating sand and clay forming the Agbada Formation. Beyond the delta front, unconsolidated, water-saturated clays are deposited and form the Akata Formations (Fig. 2).
Methodology
A multi-method approach was used for the analysis of logs in the work environment. The qualitative interpretation is based mainly on the observation and analysis of log responses. The “Quick look” method, which is a rapid interpretation of log developed by Serra (1979), is therefore used for this purpose to identify the lithology, the potential reservoirs, the producing levels and the fluids they contain. The quantitative characterization of the reservoirs is done using methods based on empirical relations integrated into the Techlog software.
The volume of shale is determined quantitatively by applying different methods. If the reservoir contains some minerals like feldspars, uranium and potassium, the GR value can be influenced and the neutron–density method is necessary (Attia 2015). Else, the analysis of the natural gamma-ray log response can be used.
These minerals are not present in our reservoir, and radioactive clay can be identified. Clays, areas with GR values ≥ 90 API; sand (clean), areas with GR values ≤ 50 API, and values between 50 and 90 API (50 < GR < 90 API), correspond to sandy-clay areas (Meunier 2011; Delalex 2014).
The clay volume \(V_{{{\text{sh}}}}\) is estimated from the linear relation applied to natural gamma-ray logs (Asquith 1982).
where:\(\begin{gathered} {\text{GR}}_{{{\text{read}}}} {\text{:~GR~value~of~the~bank~read~directly~from~the~log~}}\left( {{\text{API}}} \right){\text{~;}} \hfill \\ {\text{GR}}_{{{\text{min}}}} {\text{:~Minimum~GR~value~of~the~same~bank~}}\left( {{\text{API}}} \right){\text{~;}} \hfill \\ {\text{GR}}_{{{\text{max}}}} {\text{:~Maximum~GR~value~of~the~same~bank~}}\left( {{\text{API}}} \right){\text{~;}} \hfill \\ I_{{{\text{GR}}}} {\text{:~Gamma~ray~radiation~index~;}} \hfill \\ V{\text{sh~:~Volume~of~clay}}{\text{.}} \hfill \\ \end{gathered}\).
In terms of the clay content of these intervals, the quality of potential reservoirs identified shall be specified: the interval identified is considered sandy (sandstone) for clay content values between 10 and 25%; sandy-clay (sandstone-clay) for those ranging from 25 to 35%: and very clayey sand (strongly clayey sandstone) for clay content values ranging from 35 to 50% (Serra 1979).
A reference line defined on the gamma-ray curve makes it possible to separate the reservoir formations from the clay formations. This line is established as a function of a limit value of gamma ray, GRcutoff, which is calculated in turn from a limit clay volume (VshCutoff), which is approximately 45% (Staffan 2010). Beyond the value of the reference line (GRcutoff), the formation is no longer considered a reservoir.
where: \(\begin{aligned} {\text{GR}}_{{{\text{min}}}} {\text{:~}} & {\text{the~gamma~ray~value~read~directly~in~front~of~a~clean~sandstone~bed~;}} \\ {\text{GR}}_{{{\text{max}}}} {\text{:~}} & {\text{the~gamma~ray~value~read~directly~in~front~of~a~clay~bed~;}} \\ \end{aligned}\).
The potential reservoirs correspond to sand/sandstone intervals, with an amplitude greater than or equal to 10 m (Kiki 2018). The resistivity log (ILD) makes it possible to determine the presence of hydrocarbons. The low resistivity attests to the presence of water in the formations, while the medium (20 Ohm.m) and very high resistivity indicate the presence of hydrocarbons (oils and gases) (Meunier 2011).
The combination of the neutron and density log curves makes it possible to deduce the probable nature of the fluids that could be contained in the formations. In a reservoir potentially containing hydrocarbons, the density curve evolves to the left of the neutron curve: the inversion effect between the density and neutron curves. The assessment of the inversion effect or of the difference between the curves of the neutron and density log responses makes it possible to decide on the probable nature of the fluid. This difference between the density curve and the neutron curve is generally less than two (2) or three (3) divisions in the oil zone and greater than three (3) divisions in the gas zone (Meunier 2011; Varhaug 2016).
The porosity density is obtained from Wyllie’s formula.
Alongside this density porosity, the porosity is determined by the “Quick look” method, which combines neutron and density logs porosity \(\left( {\emptyset _{N} ,\emptyset _{D} } \right)\). The total \(\emptyset _{T}\) and effective porosity \(\emptyset _{e}\) are plotted by the following equations.
In the case of this study, we will use the relation of Coates and Dumanoir that permits us to obtain the permeability in the clean sands as in the sand-clay formations.
where:\(\begin{aligned} K: & {\text{~Permeability~}}\left( {{\text{mD}}} \right){\text{~}};{\text{~}} \\ R_{w} : & {\text{~Resistivity~of~formation~water~at~formation~temperature~}}; \\ R_{{t.irr}} : & {\text{Real resistivity of the formation at irreducible water saturation}}; \\ \emptyset \,: & {\text{ Porosity }}; \\ C \,et\,j:\,& {\text{Coates and Dumanoir constants}}. \\ \end{aligned}\).
In the case of non-proper formations, several relations have been established depending on the nature of the clays, namely: Simondoux, Modified Simondoux, Indonesian. In the case of this study, the water saturation is estimated by the method of Juharz.
where: \(\begin{aligned} S_{{wT}} :~ & {\text{Total~water~saturation}};~ \\ V_{{{\text{sh}}}} :{\text{~}} & {\text{Volume~of~clay}} \\ \phi _{T} :~ & {\text{Total~Porosity}}~; \\ \phi _{{sh}} : & ~{\text{Clay~Porosity}}~; \\ a~:~ & {\text{Formation~factor}}~; \\ n~:~ & {\text{saturation~exponent,~which~can~vary~between~1}}{\text{.2~and~2}}{\text{.2~;}} \\ m:~ & {\text{Cementation~factor}}. \\ \end{aligned}\).
Due to the water saturation, \(S_{\omega }\), it will be possible to determine the hydrocarbon saturation in the virgin zone \(~S_{{{\text{hc}}}}\) with the following formula:
Results and discussion
Lithological characteristics
Identification of lithofacies is very crucial because petrophysical parameters such as porosity, permeability and saturation depend on the type of facies. The analysis of the gamma-ray log and the superposition of the neutron–density log made it possible to determine the lithological nature of the layers crossed (Fig. 3), from the predefined electrofacies.
The cross-plots of neutron–density-gamma ray (Fig. 4) of the studied wells, allow verifying the lithology obtained from the interpretation of the gamma rays and the superposition of the neutron–density logs.
The four cross-plots show a configuration of a clayey sandstone environment. The points of lower to higher values GR around the sandstone line reflect the presence of sandstones, and the displacement of the cloud points of lower to higher GR values reflects the presence of clayey sandstones (Fig. 4). The presence of clays is materialized by the displacement of the cloud from the average points to the high GR values of the dolomite line to the right.
The cross-plot of well P1 (Fig. 4) shows a variation in porosity between approximately 35 and 45%. Some points of low value gamma ray are observed around the line of sandstones: this proves a very weak presence of very porous sandstones. There are also low to medium gamma-ray values around the limestone and dolomite lines, characterizing the presence of porous carbonate formations. In addition, well P3 shows a high occurrence of clays, indicated on the cross-plot by an abundance of medium to high gamma-ray value points beyond (right) the dolomite line.
The cross-plot of the well P2 (Fig. 4) shows a variation in porosity between 40 and 45%. A few points of low gamma-ray values are observed around the sandstone line: this proves a very low presence of very porous sandstones. There are also low to medium gamma-ray values around the limestone and dolomite lines, thus characterizing the presence of porous carbonate formations.
In addition, well P3 shows a high occurrence of clays, indicated on the cross-plot by an abundance of medium to high gamma-ray value points beyond (right) the dolomite line. The cross-plot of well P3 (Fig. 4) shows a porosity of approximately 46%. Low gamma-ray values are observed around the sandstone line; this proves the presence of very porous sandstones. There are also low to medium gamma-ray values around the limestone and dolomite lines, characterizing the presence of porous carbonate formations. In addition, well P3 shows a high occurrence of clays, indicated on the cross-plot by an abundance of medium to high gamma-ray value points beyond (right) the dolomite line.
The cross-plot of well P4 (Fig. 4) shows a variation in neutron porosity between approximately 32 and 40%. Low gamma-ray values are observed around the sandstone line; this proves the presence of very porous sandstones/sand. There are also low to medium gamma-ray values around the limestone and dolomite lines, thus characterizing the presence of porous carbonate formations. In addition, the well P4 shows a high occurrence of clays, indicated on the cross-plot by an abundance of medium to high gamma-ray value points beyond (right) the dolomite line.
Delimitation of reservoir bearing and shale volume
The analysis of the gamma-ray log allows calculating of the volume of shale (Vsh) and potential reservoir stage. The log of clay content according to the volume has been plotted (Fig. 5). The potential reservoirs which correspond to intervals of low gamma-ray values (less than the GRcutoff), and whose amplitude is greater or equal to 10 m have been identified (Fig. 5).
In well P1, five (05) potential reservoirs (R1, R2, R3, R4, R5) were detected, with varying thicknesses between 11.7 m (R4) and 75.6 m (R1). In well P2, two (02) potential reservoir levels have been identified, with thicknesses of approximately 11 m. In well P3, four (04) potential reservoirs were detected, with varying thicknesses between 12.7 m (R1) and 37.19 m (R3). In well P4, six (06) potential reservoirs were identified, with varying thicknesses between 15.12 m (R2) and 38.17 m (R4).
The average values of the clay content show that the potential reservoirs are sandy with clay volumes varying between 12.7 and 24.23% (R2, R3 and R5 of the well P1; R1 of the well P2; R1 and R3 from well P3 and R1, R2 and R5 from well P4) and sandy clay with clay volumes between 27.58 and 32.63%. We note a strong occurrence of sandy reservoirs and the presence of some very clayey sandy reservoirs. The potential reservoir level with clayey content and thickness is given in Table 1.
Petrophysical parameter
In well P1, the analysis and interpretation of the result of log (Fig. 6) exhibit five potential sandy to sandy-clay reservoir levels, with varying thicknesses between 11.7 and 75.6 m. The porosity of these reservoir levels ranges from good to excellent with values between 0.26 and 0.4. A decrease of these values is noted as a function of depth, and this is explained by the compaction caused by the overload sediments. The permeability of these five reservoir zones varies between 81.29 and 204.06 mD, characterizing average to good permeability. They equally decrease with depth, so they evolve synchronously with the porosity. The water saturation of these reservoirs (R1, R2, R3, R4 and R5) is 24.75%; 23.48%; 22.59%; 33.67% and 22.55%, respectively.
Two potential reservoir levels were identified in well P2 (Fig. 6). They are sandy clay ( R1) and very clayey sand ( R2), with thicknesses of approximately 11 m. The porosities of these reservoirs are 0.38 and 0.43, respectively. The high porosity of reservoir R2 at a depth of approximately 1020 m is induced by the micropores of the clays, which are very present in this reservoir. The permeabilities of the two reservoirs increase with depth and are estimated at 153.6 mD and 278.5 mD, respectively. The high permeability of R2 could be due to natural microfissures or fractures.
In well, P3 (Fig. 6), four potential reservoir levels with heights varying between 10 m and 43.8 m were identified. Reservoirs R1 and R4 are sand; however, reservoirs R2 and R3 are sandy clay and very clayey sand, respectively. These reservoir levels have excellent porosities: R1, R2 and R3 have an identical porosity estimated at approximately 0.34, while that of R4 is evaluated at 0.32. The permeability decreases with respect to the depth, between R1 and R3 (106.6–30.34 mD), and then increases at the level of R4 with a value of 44.35 mD. These permeabilities range from poor to moderate. The high permeability of R 4 is thought to be due to natural fractures connecting the isolated pores. Well P3 does not show any evidence which could indicate the presence of hydrocarbons. The water saturation of these reservoir levels varies between 3.37 and 43.86%.
Six potential reservoir levels, with thicknesses ranging between 11.4 and 34.5 m, were identified in well P4 (Fig. 6). These reservoir levels are generally sandy (R1, R2 and R5) to sandy clay (R3 and R6), with the R4 reservoir very clayey sand. Their porosities range from average to excellent and vary between 0.18 and 0.36. The porosity decreases up to R5 and then increases at the level of reservoir R6 with a porosity of 0.34. The permeabilities are poor (29.81 mD) to medium (70.09 mD). We note at the level of R6, an increase in porosity and permeability compared to R5, which would be due to the micropores present in the clays and the natural microfractures, respectively. The water saturations vary between 37.48% and 73.27%. The reservoir R5, likely to contain hydrocarbons (gas at a height of about 12 m and oil at a height of about 5.8 m, in this case), has a water saturation of 54.27%, that to say 45.73% of hydrocarbon saturation. The results are summarized in Table 2.
Analysis of the resistivity log shows that the zones whose resistivities vary between 20 and 2000 Ohm.m are therefore colored in yellow (Fig. 6). A strong gas effect is evidenced from the cloud point distribution in the neutron–density cross-plot of well P1 and well P4 (Fig. 4). The sandstone reservoirs corresponding to these zones are considered as potentially containing the hydrocarbons. In this context, two reservoirs (R4 and R5) in well P1 and reservoir R5 in well P4 can potentially contain hydrocarbons. The results of cloud point cross-plotting are similar to those obtained by Upal (2020) in the Sangu gas field, offshore, Bangladesh. So, gas is observed in R4 with a slope of about 2.5 m (between 1015.3 and 1017.8 m) and in the R5 over a height of about 1.6 (between 1039.1 and 1040.7 m), well P1. In well P4, the reservoir that may potentially contain hydrocarbons, i.e., reservoir R5, shows the presence of gas over approximately 12 m of coastline (between 1161.9 and 1173.9 m) and oil on a height of about 5.8 m (between 1173.9 and 1179.7 m).
In view of these characteristics, we can affirm that the potential Miocene reservoir levels identified in the four wells studied in the southwestern portion of the RDR basin have good reservoir rock qualities. Our findings will serve as useful data for future exploration campaigns and enhance the petrophysical parameters of the reservoirs of the RDR basin. The prospecting of blocks promoted by the state of Cameroon begins with a better understanding of geological and petrophysical knowledge of neighboring or operating fields in the basin. In this context, a study on the characterization of reservoirs in the Rio Del Rey basin is therefore beneficial.
Conclusion
The well-logging analysis showed that two to six potential reservoirs were identified on an ad hoc basis in the different wells studied. These reservoir levels are generally sand to clayey sand, with percentages of clay from 12.7 to 32.89%; however, there are some very clayey sand levels with clay volumes ranging between 37.19 and 41.15%. They, therefore, have significant lithological qualities. The porosities of the different potential reservoirs, obtained by the “Quick look” method (ΦQL), vary between 0.18 and 0.43 with a majority of these values greater than 30%, characterizing the excellent porosities of these reservoir formations. The majority of the potential reservoirs identified in the different wells have average permeability values varying between 52.75 and 278.5 mD, with the exception of reservoirs R3, R4 of well P3 and reservoirs R4, R5 of well P4 showing values less than 50 mD and characterizing poor permeability. The permeabilities of the reservoirs of well P1 show relatively higher permeability values than those of the reservoirs of the P2, P3 and, P4 wells.
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Domra Kana, J., Diab Ahmad, A., Gouet, D.H. et al. Sandstone reservoir characteristics of Rio Del Rey basin, Cameroon, using well-logging analysis. J Petrol Explor Prod Technol 11, 2621–2633 (2021). https://doi.org/10.1007/s13202-021-01211-4
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DOI: https://doi.org/10.1007/s13202-021-01211-4