Hostname: page-component-cd9895bd7-hc48f Total loading time: 0 Render date: 2024-12-24T17:34:10.463Z Has data issue: false hasContentIssue false

Palynostratigraphy, biochronology and palaeobathymetry of a section of Awaizombe-1 well, eastern Niger Delta, Nigeria

Published online by Cambridge University Press:  06 September 2022

Jacinta N. CHUKWUMA-ORJI*
Affiliation:
Department of Geology, Federal University of Technology, Minna, Nigeria.
*
Corresponding author. E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Ditch cuttings (69 samples) from a section of Awaizombe-1well located in the Northern Depobelt of the eastern Niger Delta Basin were used for this study. The lithology of the studied interval 1373–1812 m (439 m thick) consists of fissile grey shale and mudstone units. The scid method of sample preparation for palynormorphs’ recovery was adopted. Analysis recorded a well-preserved and diverse assemblage of palynomorphs, rich in pollen, spores and dinoflagellate cysts (dinocysts). First and last occurrences of marker and age diagnostic species were used for palynostratigraphic interpretation. Four palynostratigraphic interval range zones were established: Psilatriporites sp.–Racemonocolpites hians Zone; early Oligocene (Rupelian age), Praedapollis africanus–Doualaidites laevigatus Zone; late Eocene (Priabonian age), middle Eocene (Lutetian and Bartonian ages), Doualaidites laevigatusPraedapollis flexibilies Zone; and early Eocene (Ypresian age), Verrucatosporites usmensisRetitricolpites ituensis Zone. The first downhole occurrence of D. laevigatus at the 1482 m marks the late Eocene/early Oligocene boundary. Established zones are useful for inter and intra basins correlation. Lithology and age of the studied section are suggestive of the lower Agbada Formation. Palaeoenvironmental interpretations using diagnostic species revealed two environments: brackish and inner neritic to upper bathyal (0–600 m) under relatively warm-water marine condition indicated by thermophilic dinocyst taxa, such as Lingulodinium machaerophorum, Polysphaeridium zoharyi and Homotryblium spp. The lithology and these types of environments are good sites for hydrocarbon generation.

Type
Spontaneous Article
Copyright
Copyright © The Author(s), 2022. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

1. Introduction

The geographical coordinates of the Awaizombe-1 well are latitude 5°60′N and longitude 6°98′E, in the Northern Depobelt of the Niger Delta Basin in Nigeria (Fig. 1). The Northern Depobelt of Niger Delta Basin consists of paralic sequences capped by alluvial sands. The paralic sequence has late Eocene to early Miocene age, while the alluvial sand is of early Miocene age (Doust & Omatsola Reference Doust and Omatsola1990). Okosun & Osterloff (Reference Okosun and Osterloff2014) studied the ostracod, diatom and radiolarian biostratigraphy of the Awaizombe-1 well, Niger Delta Basin. These authors studied in detail the record of the ostracods, diatoms and radiolarians species recovered from the Awaizombe-1 well, but no research was done regarding the palynomorphs content. The present work is focused on the palynostratigraphy, biochronology and palaeobathymetric interpretation of a section (from 1373 to 1812 m depth). Palynomorphs can be very useful in the estimation of palaeobathymetry due to the reduced size, high abundance in small samples, and wide distribution over terrestrial and marine environment, high taxonomic diversity, short stratigraphic ranges, and preference for specific environmental conditions by some species. Different palynomorphs are indicators of a particular palaeodepth: bathymetry, and depositional environment; namely inner neritic, outer neritic, bathyal and abyssal (Stover et al. Reference Stover, Brinkhuis, Damassa, De Verteuil, Herby, Monteil, Partridge, Powell, Riding, Smelror, Williams, Jannsonius and McGregor1996).

Figure 1. Location of the Awaizombe-1 well (modified after Chukwuma-Orji et al. Reference Chukwuma-Orji, Okosun, Goro and Waziri2017).

2. Geology of the Niger Delta

The geology of the Niger Delta Basin comprises Akata, Agbada and Benin formations (Bankole Reference Bankole2010). The Akata Formation is generally of open marine and prodelta dark grey shale with lenses of siltstone and sandstone. The age of the Akata Formation ranges from Palaeocene in the proximal parts of the delta to recent in the distal offshore. The Agbada Formation consists of cyclic coarsening-upward regressive sequences composed of shales, siltstones and sandstones, which include delta front and lower delta plain deposits (Reijers et al. Reference Reijers, Petters, Nwajide and Reijers1996). The Agbada Formation ranges in age from the Eocene to Holocene. The Benin Formation is the uppermost unit in Niger Delta Basin. The Benin Formation comprises a succession of Oligocene to Holocene age, thick poorly indurated sandstones, thin shales, coals, and gravels of continental to upper delta plain origin. The Niger Delta Basin is one of the major regressive deltaic sequences of the world (Reijers et al. Reference Reijers, Petters, Nwajide and Reijers1996). The stratigraphic succession of the Niger Delta Basin is over 12 km thick at the depocentre and occupies an area of 75,000 km2 in the Gulf of Guinea (Ejedawe Reference Ejedawe1981).

3. Methods

The lithology of the ditch cuttings was described by means of physical observation of the samples with the aid of the chart for textural analysis of clastic sediments and a magnifying hand lens.

Sixty-nine (69) ditch cuttings from Awaizombe-1 well (interval 1373–1812 m) were processed for palynomorph recovery through the standard palynological acid maceration technique. Fifteen grams of each sample were poured into well labelled plastic cups and positioned in a fume cupboard. Each sample was digested for 35 min in 40% hydrochloric acid for removal of carbonate and 24 h in 40% hydrofluoric acid for the removal of silicate. Sieving was done using a Branson Sonifier™ to filter away any remaining inorganic matter (silicates, clay and mud) and heavy minerals to concentrate organic matter present in the sample. Controlled oxidation was given to the sieved residue using concentrated nitric acid. The residue was stained with Safranin O, strew mounted on glass slides and examined under a transmitted light Olympus CX41 microscope.

4. Results and discussion

The lithology of the studied interval 1373–1812 m (439 m thick), consists of fissile grey shale and mudstone units (Fig. 2). This is suggestive of lower Agbada Formation which is also a good hydrocarbon source rock in the Niger Delta Basin (Short & Stauble Reference Short and Stauble1967). The lower Agbada paralic units consist of thick shale unit and thin sandy units (Durugbo & Uzodimma Reference Durugbo and Uzodimma2013).

Figure 2. Palynomorph distribution chart of Awaizombe-1 well.

The result of the analysis carried out on 69 ditch cuttings of the studied Awaizombe-1 well consist of 89 palynomorphs specimens comprising 58 pollen, 11 spores, 18 dinocysts and 2 algae taxa (Fig. 2). The palynomorphs recovered are abundant, diverse and well preserved in almost all the intervals. Photomicrographs of the selected palynomorphs are presented in Fig. 3. The palynofloral assemblage was dominated by pollen and spores, namely: Acrostichum aureum; Laevigatosporites sp.; Pachydermites diederixi; Psilatricolporites crassus; Retimonocolpites obaensis; Zonocostites ramonae; Verrucatosporites sp.; and Verrucatosporites usmensis. Two algal species were identified: Botryococcus braunii; and Pediastrum sp. Notable dinocysts include: Achomosphaera ramulifera; Leiosphaeridia sp.; Lingulodinium machaerophorum; Oligosphaeridium pulcherimum; Polyspheridium zoharyi; and Spiniferites sp.

Figure 3. Microphotograph of selected sporomorph recovered.

4.1. Palynostratigraphy and biochronology

Palynostratigraphy can be defined as the application of palynological methods to stratigraphy. The first downhole occurrences (FDOs) and last downhole occurrences (LDOs) of age diagnostic palynomorphs species, such as Doualaidites laevigatus, Praedapollis africanus, Praedapollis flexibilies, Psilatriporites sp., Racemonocolpites hians, Retimonocolporites sp., Retitricolpites ituensis, Verrucatosporites usmensis and the dinocyst taxa Homotryblium oceanicum, were used for the palynostratigraphic and biochronology interpretations. Four floral biostratigraphic interval zones are established in this study (Table 1). The zones span through early Eocene (Ypresian) to early Oligocene (Rupelian) and are described from the oldest to the youngest (Table 1). The zones were recognised based on the work of Murphy & Salvador (Reference Murphy and Salvador1999).

Table 1. Established palynozones

4.1.1. Psilatriporites sp.–Racemonocolpites hians Zone (interval range zone)

Stratigraphic interval: 1482–1373 m (109 m thick).

Definition: The top of the zone is defined by the FDO of R. hians while the base is marked by the FDOs of Psilatriporites sp. and Doualaidites laevigatus. This zone is an interval range zone.

Characteristics: It is characterised by the presence of D. laevigatus and Zonocostites ramonae. Other characteristic palynomorphs within this zone include: Acrostichum aureum; Laevigatosporites sp.; Psilatricolporites crassus Pteris sp.; and Verrucatosporites sp. This zone is also characterised by the first appearance of these sporomorph taxa: Echmonocolpites gematus, Magnastriatites howardii, Monocolpites maginatus; and Spinizonocolpites echinatus; the dinocysts taxa Achomosphaera ramulifera, Leiosphaeridia sp., Lingulodinium machaerophorum, Nematosphaeropsis labyrinthea, Oligosphaeridium pulcherimum, Polyspheridium zoharyi, Spiniferites sp., and Spiniferites ramosus; and fresh water algae taxa Botrycoccus braunii and Pediastrum sp.

Age: The zone is dated early Oligocene (Rupelian age, 33.0–28.5 Ma). This zone is equivalent to the P500 zone and P520 subzone of Evamy et al. (Reference Evamy, Haremboure, Karmerling, Knaap, Molloy and Rowlands1978). The FDO of D. laevigatus at the base of the zone (1482 m) is an indication of the Eocene–Oligocene boundary (Chukwuma-Orji et al. Reference Chukwuma-Orji, Okosun and Onoruoiza2021). The FDOs of Monocolpites marginatus and Spinizonocolpites echinatus; and dinocyst taxa Oligosphaeridium sp., and Oligosphaeridium pulcherimum, within the zone are diagnostic of early Oligocene age.

4.1.2. Praedapollis africanusDoualaidites laevigatus Zone (interval range zone)

Stratigraphic interval: 1574–1482 m (92 m thick).

Definition: The top of the zone is defined by the FDO of D. laevigatus while the base is marked by the LDO of P. africanus. This zone is an interval range zone.

Characteristics: Highly abundant and diverse palynomorphs were recovered within this zone which includes Cinctiperiporites mulleri, Doualaidites laevigatus Laevigatosporites sp., Psilatricolporites crassus, Retimonocolporites obaensis, Verrucatosporites usmensis and Zonocostites ramonae, and also Leiosphaeridia sp. This abundant diversity at the upper part (1452–1604 m) may have been due to the availability of light and oxygen for photosynthesis of the taxa.

Age: The zone is dated late Eocene (Priabonian age, 33.7–33.0 Ma). This zone is equivalent to the P400 zone and P460–P480 subzone of Evamy et al. (Reference Evamy, Haremboure, Karmerling, Knaap, Molloy and Rowlands1978). The LDOs of Bombacacidites bellus and Peregrinipollis nigericus, are diagnostic of late Eocene.

4.1.3. Doualaidites laevigatusPraedapollis flexibilies Zone (interval range zone)

Stratigraphic interval: 1757–1574 m (183 m thick).

Definition: The top of the zone is defined by the LDO of P. flexibilies while the base is marked by the LDO of D. laevigatus. This zone is an interval range zone.

Characteristics: It is characterised by Acrostichum aureum, Cinctiperiporites mulleri, Doualaidites laevigatus, Laevigatosporites sp., Pachydemites diederixi, Psilatricolporites crassus and Zonocostites ramonae. The only (first and last) occurrence of Gemmatricolporites sp. at a depth of 1623 m was recorded within this zone.

Age: The zone is dated middle Eocene [Lutetian (49.0–41.3 Ma)–Bartonian (41.3–37.0 Ma) age]. This zone is equivalent to the P400 zone and P420–P450 subzone of Evamy et al. (Reference Evamy, Haremboure, Karmerling, Knaap, Molloy and Rowlands1978). The LDOs of Retibrevitricolporites protrudens and Ctenolophonidites costatus are diagnostic of middle Eocene (Legoux Reference Legoux1978).

4.1.4. Verrucatosporites usmensisRetitricolpites ituensis Zone (interval range zone)

Stratigraphic interval: 1812–1757 m (55 m thick).

Definition: The top of the zone is defined by the FDO of R. ituensis while the base is marked by the last LDO of V. usmensis, Retimonocolporites sp.

Characteristics: The zone is characterised by few recoveries of palynomorph taxa and absence of Botryococcus braunii and Pediastrum sp., suggesting no freshwater incursion within the interval. It is also characterised by considerably abundant recoveries of Laevigatosporites sp., Psilatricolporites crassus, Retimonocolpites obaensis, Spinizonocolpites echinatus, Verrucatosporites usmensis, Verrucatosporites sp., and Leiosphaeridia sp.

Age: The zone is dated Early Eocene (Ypresian age, 54.8–49.0 Ma). This zone is equivalent to the P300 zone and P430 subzone of Evamy et al. (Reference Evamy, Haremboure, Karmerling, Knaap, Molloy and Rowlands1978). The occurrence of Monoporites annulatus, Psilatricolporites cursus, Retitricolporites irregularis and Verrucatosporites usmensis are also diagnostic of early Eocene.

4.2. Palaeoenvironmental/palaeobathymetric interpretation

Palaeobathymetry of the Awaizombe-1 well was determined using the occurrences, co-occurrences and relative abundances of microfloral elements that are indicative of palaeo-water depth. The composition and relative abundance of different types of palynomorphs are indicative of changes in palaeobathymetry. Marine indicators such as dinocysts are ideal for palaeoenvironmental interpretations (Stover & Williams Reference Stover and Williams1982). They tend to be most abundant in rocks deposited in middle neritic to upper bathyal environments and their abundance decreases landward. Dinocysts used in palaeoenvironmental interpretation include: Homotryblium oceanicum and zoharyi (these taxa are common in inner neritic to oceanic warm and high saline water environments, in subtropical to tropical regions, which may have a high productivity); Lingulodinium machaerophorum (it is assigned to inner neritic environments with low to normal salinity and warm temperate water species and an indicator of nutrient enrichment reflecting increased productivity and may proliferate in the vicinity of the active upwelling cells or near river mouths); Achomosphaera sp., Hystrichosphaeropsis minimum, Spiniferites sp., Spiniferites mirabilis (these taxa are assigned to neritic to oceanic setting with stable salinity, this group can be cosmopolitan and also can reach high relative abundances in high productivity areas such as upwelling regions and areas influenced by river discharge); Nematosphaeropsis labyrinthea (this taxa is related to outer neritic to oceanic environments, its occurrence can also indicates an increase in sea level); and Leisphaeridia sp. is suggestive of an outer neritic to upper bathyal (Stover et al. Reference Stover, Brinkhuis, Damassa, De Verteuil, Herby, Monteil, Partridge, Powell, Riding, Smelror, Williams, Jannsonius and McGregor1996; Chekar et al. Reference Chekar, Slimani, Jbari, Guédé, Mahboub, Asebriy and Habiba Aassoumi2018). Other occurring palynomorphs include spores, pollens, bissacate pollen and algae (Fig. 4). Palynomorphs’ distribution presented in Figs 2, 4 represent a schematic model of the palaeobathymetry. The palaeoenvironmental interpretations of the studied well, can be inferred as follows:

Figure 4. Schematic model of the dinocysts and other palynomorph distribution patterns from continental shelf–slope (modified after Stover et al. Reference Stover, Brinkhuis, Damassa, De Verteuil, Herby, Monteil, Partridge, Powell, Riding, Smelror, Williams, Jannsonius and McGregor1996).

The interval of 1373 to 1391 m is inferred to have been deposited in brackish (terrestrial) environment due to the preponderance of Acrostichum aureum, Psilatricolporites crassus and Zonocostites ramonae (brackish water indicators), and the absence of marine dinocysts’ indicators. The following taxa occurring within this interval are: Racemonocolpites hians; Arecipites exilimuratus; Verrucatosporites usmensis; Retimonocolpites obaensis; Striatricolporites catatumbus; Verrucatosporites sp.; Laevigatosporites sp.; Retitricolporites irregularis; Retbrevitricolporites protrudens; and Cinctiperiporites mulleri. These taxa suggest brackish (terrestrial) environment.

The interval of 1391 to 1812 m is inferred to have been deposited within inner neritic to upper bathyal environments (0–600 m). This deduction is due to the occurrences of Leisphaeridia sp. throughout the interval. Other dinocysts recorded within the interval include: Spiniferites sp.; Spiniferites mirabilis; Spiniferites ramosus; Hystrichosphaeropsis minimum; Lingulodinium machaerophorum; Homotryblium oceanicum; Polysphaeridium zoharyi (temperate to tropical species); and Achomosphaera ramulifera, Achomosphaera sp., Nematosphaeropsis labyrinthea (cool to temperate species) (Stover et al. Reference Stover, Brinkhuis, Damassa, De Verteuil, Herby, Monteil, Partridge, Powell, Riding, Smelror, Williams, Jannsonius and McGregor1996). The presence of the observed cool to temperate taxa within this interval may have been due to cryospheric circulation of ocean currents in areas of upwelling or the Palaeocene–Eocene Thermal Maximum of this time. The occurrence of Botrycoccus braunii and Pediastrum sp. algal species within 1446–1726 m suggests fresh water incursion. The presence of thermophilic dinocyst taxa such as Spiniferites ramosus, Spiniferites ramosus, Spiniferites sp., Polysphaeridium zoharyi, Lingulodinium machaerophorum, and Homotryblium sp. suggest warm-water marine conditions with salinity of 7–10% within tropical latitudes.

5. Conclusion

The palynological analysis of the Eocene–Oligocene succession from a section of the Awaizombe-1 well in the Northern Delta Depobelt of eastern Niger Delta reveals the presence of well-preserved and diverse assemblage of palynomorph, rich in pollen, spores and dinoflagellate cysts (dinocysts). The palynomorph marker events used for the biostratigraphic interpretations include the first and last occurrences of marker species, such as Racemonocolpites hians, Psilatriporites sp. and Doualaidites laevigatus, Praedapollis africanus, Homotryblium oceanicum, Praedapollis flexibilies, Retitricolpites ituensis, Verrucatosporites usmensis, and Retimonocolporites sp. The following interval range zones were established: Psilatriporites sp.–Racemonocolpites hians Zone; Praedapollis africanus–Doualaidites laevigatus Zone; Doualaidites laevigatusPraedapollis flexibilies Zone; and Verrucatosporites usmensisRetitricolpites ituensis Zone. The lowermost part of the Awaizombe-1 well is assigned to the Early Eocene (Ypresian age), the middle section is assigned Middle Eocene (Lutetian and Bartonian) and its upper part to the Late Eocene (Priabonian) and Early Oligocene (Rupelian). The FDO of D. laevigatus at the 1482 m is an indication of the late Eocene–early Oligocene boundary. The assigned age to the studied interval agrees with the previous work which stated that the Northern Delta Depobelt ranges from Eocene to Miocene (Doust & Omatsola Reference Doust and Omatsola1990). The established interval biozones are useful for inter and intra basin biostratigraphic correlations. Qualitative and quantitative analyses permit palaeoenvironmental and palaeobathymetric interpretations. The occurrences of dinocyst groups, spores and pollen lead to the distinction of two environments: brackish (terrestrial) and inner neritic to upper bathyal (0–600 m) under relatively warm-water marine conditions with salinity of 7–10% within tropical latitudes. These types of environments are good sites for hydrocarbon generation.

6. Conflicts of interest

None.

References

7. References

Bankole, S. I. 2010. Palynology and stratigraphy of three deep wells in the Neogene Agbada Formation, Niger Delta, Nigeria. Implications for petroleum exploration and paleoecology. PhD thesis, der Technischen Universität Berlin, 1190.Google Scholar
Chekar, M., Slimani, H., Jbari, H., Guédé, K. E., Mahboub, I., Asebriy, L. & Habiba Aassoumi, H. 2018. Eocene to Oligocene dinoflagellate cysts from the Tattofte section, western External Rif, northwestern Morocco: paleoenvironments and paleoclimate. Palaeogeography, Palaeoclimatology, Palaeoecology 507, 97114.CrossRefGoogle Scholar
Chukwuma-Orji, J. N., Okosun, E. A., Goro, I. A. & Waziri, S. H. 2017. Palynofacies, sedimentology and palaeoenvironment evidenced by studies on IDA-6 well, Niger Delta, Nigeria. Paleoecology of Africa 34, 87105.Google Scholar
Chukwuma-Orji, J. N., Okosun, E. A. & Onoruoiza, A. L. 2021. Palynostratigraphy and paleobathymetric studies of XAD-1 well Niger Delta Basin, Nigeria. Journal of Mining and Geology 57, 193202.Google Scholar
Doust, H. & Omatsola, E. 1990. Niger Delta biostratigraphy divergent/passive margin basins. American Association of Petroleum Geologists Memoir 48, 201–38.Google Scholar
Durugbo, E. U. & Uzodimma, E. 2013. Effects of lithology on palynomorph abundance in wells X1 and X2 from the Western Niger Delta, Nigeria. International Journal of Geology, Earth and Environmental Sciences 3, 170–9.Google Scholar
Ejedawe, J. E. 1981. Patterns of incidence of oil reserves in Niger Delta basin. American Association of Petroleum Geologists Bulletin 65, 1574–85.Google Scholar
Evamy, B. D., Haremboure, J., Karmerling, P., Knaap, W. A., Molloy, F. A. & Rowlands, P. H. 1978. Hydrocarbon habitat of the Tertiary Niger Delta. American Association of Petroleum Geologists Bulletin 62, 139.Google Scholar
Legoux, O. 1978. Quelques espéeces de pollen caractéristique du Néogène du Nigéria [Some characteristic pollen species of the Neogene of Nigeria]. Bulletin des Centres de Recherche Exploration-Production d'Elf-Aquitaine 2, 265317. [In French.]Google Scholar
Murphy, M. A. & Salvador, A. 1999. International Stratigraphic Guide – An abridged version, International Subcommission on Stratigraphic Classification of IUGS, International Commission on Stratigraphy. Special Episodes 22, 255–72.CrossRefGoogle Scholar
Okosun, E. A. & Osterloff, P. 2014. Ostracod, Diatom and Radiolarian Biostratigraphy of the Niger Delta. Earth Science Research 3, 7293.Google Scholar
Reijers, T. J. A., Petters, S. W. & Nwajide, C. S. 1996. The Niger Delta basin, sedimentary geology and sequence stratigraphy. In Reijers, T. J. A. (ed.) Selected chapters on geology, 100–17. Warri: SPDC Corporate Reprographic Services.Google Scholar
Short, K. C. & Stauble, A. J. 1967. Outline of the geology of Niger Delta. American Association of Petroleum Geologists Bulletin 51, 761–79.Google Scholar
Stover, L. E., Brinkhuis, H., Damassa, S. P., De Verteuil, L., Herby, R. J., Monteil, E., Partridge, A. D., Powell, A. J., Riding, J. B., Smelror, M. & Williams, G. L. 1996. Mesozoic–Tertiary dinoflagellates, acritarchs and prasinophytes. In Jannsonius, J. & McGregor, D. C. (eds) Palynology: principles and applications Vol. 2, 641750. College Station, Texas: American Association Stratigraphic Palynologists Foundation.Google Scholar
Stover, L. E. & Williams, G. L. (1982). Dinoflagellates, Third North American Paleontological Convection, Proceedings 2, 525–33.CrossRefGoogle Scholar
Figure 0

Figure 1. Location of the Awaizombe-1 well (modified after Chukwuma-Orji et al. 2017).

Figure 1

Figure 2. Palynomorph distribution chart of Awaizombe-1 well.

Figure 2

Figure 3. Microphotograph of selected sporomorph recovered.

Figure 3

Table 1. Established palynozones

Figure 4

Figure 4. Schematic model of the dinocysts and other palynomorph distribution patterns from continental shelf–slope (modified after Stover et al. 1996).