Abstract
Among the various techniques available, the geochemical technique involving total organic carbon content (TOC) and rock-eval pyrolysis are regularly being used in hydrocarbon exploration. They provide information on the kerogen type, sedimentary environment, effective source rock identification and its thermal maturity. In the present study, core samples from three deep boreholes in Krishna–Godavari basin are analyzed to understand the hydrocarbon scenario in parts of the basin. Based on TOC and rock-eval pyrolysis significantly thick, indigenous immature to early mature gas-prone shales from borehole GERMI #1; while non-indigenous, early mature to mature oil and gas-prone shales from borehole GERMI #2 and GERMI #3. Interpreted hydrocarbon typing is supported by well-testing analysis. Break in vitrinite reflectance (Ro) profile is also observed; indicative of significant erosion during Late Cretaceous sedimentation due to tectonic uplift during this time and associated high heat flow causes for thermal maturation of overlying units.
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Introduction
There are three major sedimentary basins along the east cost of India, namely, the Cauvery, the Krishna–Godavari and Mahanadi. Among three sedimentary basins, Krishna–Godavari (KG) basin located between the major rivers Krishna and the Godavari and also extending offshore, has attracted many oil and gas companies due to its richness in hydrocarbon potential. The location map of exploration block KG-OSN-2001/3 in Krishna–Godavari basin along with the boreholes is shown in Fig. 1. This block comprises an area of 1,850 km2 in NE–SW trending Krishna–Godavari (KG) Basin and is located on the eastern coast of the Andhra Pradesh, India (Tidar and Budi 2005). It represents typical divergent passive margin of east coast. It is a proved petroliferous basin (Rai et al. 1998; Biswas 1998) with an aerial extent of 15,000 km2 on land and about 25,000 km2 of adjoining offshore area up to 1,000 m isobaths line (Kumar 1983). The detailed general geology and tectonics of the basin has already been described (Gupta 2006; Rao 2001). The well-known major Godavari rift extends both onland and offshore. On land, it is exposed near Wardha towards the north western direction and extends to the sea in the south east direction. In the seaward portion, it crosses the shelf and enters the deep sea. The generalized stratigraphy of Krishna–Godavari basin is shown in Fig. 3. It contains the rocks from Cretaceous to Tertiary, different rock types are sand, sandstone, mudstone, shale, clay, siltstone, silt, volcanic and limestone (IHS 2005). The Godavari Graben is filled with a maximum of 2.8-km-thick Early Gondwana (Late Permian to Early Triassic) sediments (Kaila et al. 2005). In between these horst structures, three sub-basins are, namely, Krishna, West Godavari and the East Godavari. The basin is dominated by deltaic plains near the sea–land boundary. From the study of gravity anomalies, three basins have been characterized separated by the two basement horsts namely, Bapatla and Tanuku (Venkatarangan and Ray 1993; Murthy et al. 1995; Subrahmanyam et al. 2008; Murthy et al. 2010). The basin has significant hydrocarbon potential both in the Tertiary delta as well as in the channel–levee–overbank play types in the deepwaters (Saxena et al. 2011).
Three important geological units of KG basin are Northern graben, the central Horst and several sub-basins (Fig. 2). Unlike other basins on the east coast of India, the KG basin is considered to be unique in nature as it is reported that hydrocarbon potential identified in almost all the stratigraphic formations. For example, Triassic Mandapeta formation, Late Jurassic Gollapalli formation, Early Cretaceous Raghavapuram formation, Late Cretaceous Tirupati formation, Eocene Pasarlapudi formation, Eocene–Oligocene–Miocene Matsyapuri formation/Ravva formation and Pliocene Godavari clay formations, all know to be rich in hydrocarbons (Fig. 3). More prominently, the Ravva structure and Godavari formation of Paleocene period are all known to contain significant hydrocarbon potential (Govindan 1984) and thus the basin has emerged as one of the most promising area for exploration. These reservoirs have been charged at different maturity levels of corresponding sources within different stratigraphic sequences (Saxena et al. 2011).
In this region, recently 15 TCF of gas initially in-place (GIIP) and 38,000 barrels oil is proved through exploration drilling process (IHS 2005). Although much of the area on the land has been investigated in detail, the offshore region is relatively poorly investigated due to high cost of drilling in offshore region. In view of this, it is necessary to make a detailed and careful analysis of the meagerly available data from the offshore boreholes. In view of the above, present study is aimed to make a detailed analysis of a few borehole core samples from three deep offshore wells using the well-known TOC and rock-eval pyrolysis tools.
Sampling and methodology
The data acquired for the present study are mainly related to three offshore deep boreholes of KG basin (Table 1). The appropriate location of the wells namely GERMI #1, GERMI #2 and GERMI #3 are presented in Fig. 4. From these three boreholes, a number of 38 drillcore samples have been subjected to detailed analysis for TOC and rock-eval pyrolysis. Rock-eval pyrolysis study of samples has been carried out in ACS lab (Tidar and Budi 2005). In general, samples with TOC values greater than 0.5 % for shales and 0.3 % for carbonates are considered suitable for rock-eval pyrolysis. Rock samples are pyrolyzed using Rock-Eval 6 apparatus at ACS core laboratory. This technique evaluates oil and gas potential, the generation, thermal maturity and identifies organic matter type (Peters 1986; Tissot and Welte 1978). This instrument uses a ramped temperature pyrolysis technique, whereby a small amount of sample (70–100 mg) is heated in an inert atmosphere (helium or nitrogen) and also combusted with air to obtain several key geochemical parameters relating to the hydrocarbon potential of the rock such as the total organic carbon (TOC), type or quality of organic matter and maturity level (Peters 1986; Lafargue et al. 1998; Behar et al. 2001).
Results and discussions
Depth ranges of well bore ranges from 2,300 to 5,100 m covering the Early Cretaceous, Paleocene and Early Eocene. Figure 5 shows the relationship between hydrogen index (HI) and Tmax values in these sediments from GERMI #1, 2 and 3 in KG Basin. Thermal alteration pathways of organic matter Types-I, -II, and -III are indicated by dashed lines. Solid lines indicate approximate vitrinite reflectance values (not measured) that define the “oil window”. The geochemical results are plotted and also interpreted on hydrocarbon generation using hydrogen Index as a function of temp, oxygen index, TOC, etc. Plotting Tmax versus HI shows the different maturation paths of different kerogen types (Fig. 5). Tmax values correlate directly with vitrinite reflectance values. The type and maturity of organic matter in petroleum source rocks have been characterized from rock-eval pyrolysis data (Fig. 6). Geochemical parameters including HI [hydrogen index, (S2/TOC) × 100], OI [oxygen index, (S3/TOC) × 100] and PI [production index, S1/(S1 + S2)] are calculated. S1 versus TOC plot gives a clear indication of the indigenous hydrocarbons and non-indigenous hydrocarbons (Fig. 7). Pyrolysis experiments were repeated for some samples at early sample weight to ensure that the rock-eval/TOC detector was not overloaded by generated hydrocarbons during the original runs (Ibrahimbas and Riediger 2002).
The analytical procedure, discussion and details of rock-eval pyrolysis parameters are available in Peters (1986) and Snowdon et al. (1998). Table 2 provides an interpretive guidelines based on S2 values from rock-eval pyrolysis. Accordingly, the present study objectives are aimed to evaluate the hydrocarbon source potential from the available core sample data and to study the thermal maturity of the geological sequence in parts of KG basin.
Source facies and TOC
Geochemical data reveal that interval 2,325–2,420 m (Early Eocene) TOC contents recorded are good to very good (1.64–2.59 wt %). Rock-eval pyrolysis data reveal moderate potential yields (S1 + S2 = 2.99–4.87 mg HC/g rock). Figure 9 indicates a fair hydrocarbon source potential. Hydrogen indices were recorded (171–178) implying the presence of predominantly humic gas-prone kerogen (Type-III). Rock-eval pyrolysis reveals an average potential yield (S1 + S2 = 1.09 mg HC/g rock) and a low hydrogen index (=128 mg HC/g organic carbon) (Figs. 6, 8). The data suggest the sample has fair hydrocarbon source potential and contain predominantly gas-prone kerogen and has been cross-checked with well-testing reports (Kaawache and Mahapatra 2005). Visual kerogen composition data confirm the presence of predominantly of non-fluorescent kerogen (58 %) and vitrinite particles/Type-III kerogens (30 %) (Fig. 6).
Hydrogen indices (10–87 mg HC/g organic carbon) suggest the presence of gas-prone kerogen (Type-III). This is also confirmed by visual kerogen typing analysis, which was performed on all samples interval 4,070–5,050 m (Early Cretaceous) comprise mainly medium dark grey to olive grey claystones and medium dark grey to dark grey shales. TOC contents for these samples range from 0.20 to 2.88 wt%. Rock-eval pyrolysis analysis reveal low to moderate hydrogen indices (ranging from 11 to 185 mg HC/g organic carbon) implying the presence of predominantly gas-prone kerogen (Type-III) (Fig. 8). Visual kerogen typing analysis performed on these samples show the abundance of non-fluorescent amorphous debris (10–73 %), with secondary amounts of vitrinite particles (7–56 %). Toward the base the kerogen are dominated by vitrinite, semifusinite and inertinite maceral.
In GERMI #2 the conventional core samples from the depth range of 2,385–5,718 m are taken for TOC determination. Overall, the samples contain relatively low TOC (<2 %) indicative of poor to moderate organic richness. However, the low TOC contents suggest the section has little potential for hydrocarbon generation (Fig. 8). The rock-eval pyrolysis indicates the potential source to be gas prone at best. S1 + S2 versus TOC plots of samples indicating fair to good source rock potential of samples from GERMI #2 (Fig. 9). Based on Tmax values between 370 and 431 °C, the Late Claystone section appears to be immature to marginally mature (Fig. 9). The early value of Tmax 370 °C could be due to the presence of free hydrocarbons. Hydrogen indices (HI) (~164 to 443 mg HC/g organic carbon) and suggest that the samples are oil prone (Fig. 5). Between 3,538.5 and 5,717.5 m the TOC value ranges from 0.1 % (5,447.5 m) to 3.71 % (5,717.5 m), with most values between 0.4 and 1.5 % (fair to good) except some higher TOC values at 5,712.5 m, which is because of presence of coal. S1 values ranges from 2.18 to 29.6 mg HC/g rock characterizing excellent levels of free hydrocarbons, except 0.9 mg/g value at 4,488.9 m. Hydrocarbon generating potentials are poor to moderate (S2 values between 0.26 and 3.38 mg HC/g rock) and Tmax values between around 420 and 450 °C reflect immaturity to maturity (Fig. 9). Low Tmax values below 400 °C are likely to be artifact, caused by Tmax suppression due to the presence of considerable level of free hydrocarbons (S1). HI vary between 30 mg HC/g organic carbon (gas) and 311 (gas and oil), with most values indicating a more gas-prone character of the source sediments than the oil. Interpreted hydrocarbons are matching with well-testing reports (Asianto and Losier 2007; Asianto and Rosier 2007).
The number of samples from GERMI #3 are very limited (Fig. 4) but still those sample were showing HI in the range of 32–50 mg HC/g organic carbon with most value indicating the gas-prone character of the sediments. The hydrocarbon generation potential varies from poor to moderate (Fig. 6). The obtained geochemical results have been confirmed from well-testing reports (Maclennan et al. 2007; Jong and Pelser 2007). Due to side tracking borehole GERMI #3 has got three samples for which geochemical analysis has been carried out.
Maturity evaluation, vitrinite reflectivity analysis
In GERMI #1 a total of 30 samples throughout the interval 2,325–5,050 m were submitted for vitrinite reflectivity analysis (polished whole rock). The results are generally fair to good based on variably low to abundant recoveries of vitrinite particles. Samples from depth 2,672, 4,900, 4,995, 5,010 and 5,050 m were found to be barren of indigenous vitrinite particles (Asianto and Losier 2007; Asianto and Rosier 2007). Recorded mean vitrinite reflectivity values range from 0.52 % Ro (at 2,325 m) to 0.55 % Ro (at 2,545 m) (Fig. 10). The interpreted vitrinite reflectivity profile shows that the section is marginally mature for oil generation. Below 3,492 m there is a rapid increase in vitrinite reflectivity values from late mature to post mature. The Ro values increase uniformly from 0.98 % Ro (at 3,492 m) to 1.16 % Ro (at 4,795 m) indicating that the section is late mature for oil generation (Fig. 10). As mentioned earlier, sample 2,672 m was found barren of indigenous vitrinite particles. It is noted however, that spore colouration analysis on this sample (discussed below) confirms it is marginal mature for oil generation. Hence, the rapid increase in vitrinite reflectivity within the interval 2,673–3,492 m is thought to be associated with a significant unconformity which occurs at depth c. 2,675 m.
The argillaceous sediments analyzed throughout the sequence (interval 2,325–5,050 m, Early Eocene to Early Cretaceous) display variably very low to good organic richness (TOC in the range of 0.20–2.88 wt%). These sediments are considered to have poor to fair hydrocarbon source potential (S1 + S2 = 0.09–4.87 mg HC/g rock) and contain mainly gas-prone kerogen based on low to moderate HI values (11–185 mg HC/g organic carbon). Visual kerogen analysis on these samples confirms the presence of predominantly gas-prone kerogen (90–99 %). The gas-prone kerogen consists of vitrinite maceral and non-fluorescent amorphous debris. The non-fluorescent amorphous material is possibly sapropelic debris which has been affected by thermal maturity.
Conclusions
Based on the detailed analysis of the rock samples from three different deep offshore wells, the following major conclusion can be drawn.
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A break in maturity profile observed in GERMI #1 suggests that there is a significant amount of erosion. This area is known to be tectonically active; it can be interpreted that the erosion might have taken place during the uplifted period prior to deposition of overlying formation. Additionally, reported high heat flow values have been contributed significantly for the maturity levels. From the extrapolation of Ro profile to the surface indicates that the reaction might be at a much deeper depth of burial and have experienced high temperature. There could be alternate interpretation of the break in maturity profile of the well. However, additional data like FAMM (fluorescence alteration of multiple macerals), VIRF (vitrinite inertinite reflectance and fluorescence) and burial history modeling are required.
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S1 versus TOC plot indicates possible indigenous hydrocarbons from borehole GERMI #1 while non-indigenous hydrocarbons from boreholes GERMI #2 and GERMI #3.
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Different rock-eval pyrolysis parameters are suggestive of immature to early mature gas-prone shales from borehole GERMI #1 while early mature to mature oil and gas-prone shales from borehole GERMI #2. Limited samples from GERMI #3 are indicative of immature shales. Well-testing analysis also supports the type of hydrocarbons interpreted.
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Acknowledgments
We would like to express our deep gratitude to Gujarat State Petroleum Corporation Ltd. (GSPC) for their support and permission in getting this paper published. We are also grateful to the staff of GERMI and GSPC for sharing their interpretation insights throughout several brainstorming sessions. Thanks are also due to those who helped in their own way to get this study completed.
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Ramachandran, K., Babu, V., Behera, B.K. et al. Source rock analysis, thermal maturation and hydrocarbon generation using rock-eval pyrolysis in parts of Krishna–Godavari basin, India: a case study. J Petrol Explor Prod Technol 3, 11–20 (2013). https://doi.org/10.1007/s13202-012-0041-y
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DOI: https://doi.org/10.1007/s13202-012-0041-y