Abstract
The palaeoenvironments of the upper Palaeozoic succession in the eastern foot slopes of the Northern Galala Plateau, west of the Gulf of Suez, Egypt, are interpreted based on a detailed study of the sequence-stratigraphic framework, sedimentary facies and trace fossils. The upper Carboniferous–lower Permian Aheimer Formation has been studied in its type section exposed in Wadi Aheimer. Three unconformities bound four 3rd-order depositional sequences, including the upper Carboniferous DS NG 1, and the lower Permian DS NG 2‒4. These sequences are correlated with their counterparts on the North African and Arabian plates. The sedimentary facies characteristics indicate palaeoenvironments ranging from fluvial, estuarine, intertidal, shallow subtidal, shoreface to offshore transitional settings. The abundant and diverse ichno-assemblages are composed of horizontal, vertical and sub-vertical traces. At least 26 ichnotaxa have been identified, representing suites of the Glossifungites, proximal Cruziana, and proximal-archetypal Cruziana ichnofacies. Ichnofabric analysis revealed three distinct ichnofabrics: Tisoa, Schaubcylindrichnus and Zoophycos ichnofabrics. The trace and body fossil distribution and trophic structure of some of the recorded faunal assemblages confirm relatively stable and low-stress shallow-marine environments. In contrast, the trophic structure of some other assemblages indicates the influence of particular environmental parameters, including substrate consistency, bathymetry, water energy, productivity, rate of sedimentation, salinity and oxygen availability. The integrated results indicate that the sequences were formed during an interval dominated by different perturbations that resulted in a wide spectrum of depositional features. Moreover, evidence for Carboniferous–Permian glaciation is tentatively established in North Egypt but require further investigations.
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Introduction
Of the upper Palaeozoic of NE Egypt, the Permo-Carboniferous rocks occur on both sides of the Gulf of Suez, including the Northern Galala Plateau (NGP), Wadi Araba, the Southern Galala Plateau and west-central Sinai (Said 1962, 1971; Abdallah and Adindani 1963; Omara 1965; Issawi and Jux 1982; Kora 1984, 1998; Bandel and Kuss 1987; Klitzsch 1990; Klitzsch et al. 1990; Darwish 1992; El-Barkooky 1994; Issawi et al. 1999; Afify et al. 2023). As a consequence, different lithostratigraphic schemes have been proposed to describe the Permo-Carboniferous deposits in NE Egypt (Table 1) and the correlations of these successions in that region remain a debatable issue.
Carboniferous‒Permian rocks crop out in the eastern foot slopes of the NGP, west of the Gulf of Suez, Egypt (Fig. 1a‒c), forming a remarkable narrow strip of dark-coloured sediments. These strata represent the oldest rock units in this region, underlying different horizons of the Permo‒Triassic, Jurassic and lower Cretaceous sandstones (e.g., Said 1962, 1990; Abdallah and Adindani 1963; Issawi et al. 1999). Stratigraphical, sedimentological and palaeontological studies of these upper Palaeozoic deposits have been undertaken for over a hundred years (Schweinfurth 1885; Nakkady 1955; Kostandi 1959; Abdallah and Adindani 1963; Issawi and Jux 1982; Bandel and Kuss 1987; Kora and Mansour 1992; El-Barkooky 1994; Kora 1998). The successions record fluvial to marginal-marine depositional systems (e.g., Bandel and Kuss 1987) that developed on the south-western margin of the Palaeo-Tethys Ocean (Fig. 1d) (Scotese 2013). In general, siliciclastic deposits dominate these successions, intercalated with minor carbonates (Abdallah and Adindani 1963; Bandel and Kuss 1987). Deposition was controlled mainly by relative sea-level fluctuations combined with high terrigenous influx (e.g., Bandel and Kuss 1987).
Carboniferous‒Permian deposits of the eastern side of the NGP contain a sporadic and moderately to poorly-preserved macro-invertebrate fauna, including brachiopods, bivalves, crinoids, rugose corals and bryozoans (Abdallah and Adindani 1963; Herbig and Kuss 1988; Kora and Mansour 1992; Kora 1998). In addition, these sediments yield a variety of microfaunal (foraminifera and conodonts) and floral associations (Omara and Vangerow 1965; Said and Eissa 1969; Bandel and Kuss 1987; Lejal-Nicol 1990), studied mostly from taxonomic and palaeobiogeographic points of view.
The Carboniferous‒Permian sediments of the eastern side of the NGP are highly burrowed (Abdallah and Adindani 1963; Bandel and Kuss 1987; Kora and Mansour 1992; El-Barkooky 1994), representing relatively diverse ichno-assemblages. However, no study has yet focused on the analysis of the trace fossils in this area, which in turn has led to a generalized lack of detailed facies analysis along with palaeoenvironmental interpretations. Therefore, the present study aims to (1) interpret the environmental conditions that prevailed during deposition of the Carboniferous‒Permian succession exposed in the eastern side of the NGP based on description of its sequence-stratigraphic framework, litho- and ichno- facies, and (2) discuss the various factors controlling the occurrence and distribution of the identified trace fossils. The present work is based on the succession exposed in the Wadi Aheimer area (29°30′38.52"N, 32°23′51.46"E), about 19 km SSE of Ain Sukhna and about 6 km NW of Bir Abu Darag along the Suez-Gharib road, in the northern Eastern Desert of Egypt (Fig. 1b, c).
Geological setting
During Palaeozoic times, North Africa was located on the southern margin of the Palaeo-Tethys Ocean (Fig. 1d; Guiraud et al. 2001, 2005; Scotese 2013). The assembly of Pangaea in the Late Palaeozoic was completed by the closing of Palaeo-Tethys along with the complex collision of Gondwana with Laurussia. During this growth of the supercontinent, several factors affected facies development across this continental shelf comprising rifting, basin sagging, compressive tectonics and sea-level fluctuations (Guiraud et al. 2005; Craig et al. 2008).
In North Africa, including Egypt, the Early Carboniferous witnessed a global rise in sea level, invading eastern Libya (e.g., Guiraud et al. 2001, 2005; Carr 2002). In the northern part of the Western Desert of Egypt, in contrast, a shallow-marine siliciclastic platform developed (e.g., Keeley 1989), passing eastwards into a mixed siliciclastic-carbonates platform (i.e., the Um Bogma Formation in west-central Sinai) (Table 1; Kora 1984, 1998). A similar mixed siliciclastic-carbonate platform was developed along the northernmost margin of Algeria, Tunisia and Morocco (Guiraud et al. 2005; Craig et al. 2008). The latest Early Carboniferous registered some tectonic instability, recorded by unconformities in Egypt and Libya (Wennekers et al. 1996; Guiraud and Bosworth 1999), as well as in north-western Africa (Fabre 1988; Craig et al. 2008). During the early Westphalian, the marine conditions were restricted to north-eastern Egypt (both sides of the Gulf of Suez) and Cyrenaica (Guiraud et al. 2001, 2005; Craig et al. 2008). Sea level rose during the late Westphalian‒Stephanian and a mixed carbonate siliciclastic platform fringed the North African-Arabian margin, including the western side of the Gulf of Suez (Issawi et al. 1999; Guiraud et al. 2001, 2005).
Over large areas in the Near East and North Africa, including the study area, a major unconformity marks the Carboniferous/Permian transition (Gvirtzman and Weissbrod 1984; Wennekers et al. 1996; Kora 1998; Guiraud et al. 2001, 2005; Craig et al. 2008), a consequence of uplift during the main phase of the Hercynian Orogeny. During the Early Permian, rift basins formed along the northern margins of Africa were filled by thick continental (Morocco–Algeria), mixed (Egypt), or marine sediments (S Tunisia–NW Libya) (Guiraud et al. 2005; Craig et al. 2008). These rifting events increased through the Permian (Guiraud et al. 2005), whereas subsidence affected the eastern Mediterranean margin in conjunction with the opening of the Neo-Tethys Ocean (e.g., Stampfli and Borel 2002).
The opening of the Atlantic Ocean in Triassic to Early Cretaceous times led to important extensional phases in North Africa (Craig et al. 2008 and references therein). During the Late Cretaceous and in conjunction with the onset of rifting in the northern North Atlantic and the collision between the African and European plates, a compressional regime (i.e., Alpine compression) dominated North Africa, including Egypt, and resulted in further folding, thrusting, intra-plate inversion and uplift (Maurin and Guiraud 1993; Guiraud et al. 2001, 2005; Craig et al. 2008). During Oligo‒Miocene times, the north-eastern corner of Africa was affected by a major rifting phase that led to the development of the Red Sea, Gulf of Suez and Gulf of Aqaba rift systems (Meshref 1990; Patton et al. 1994; Guiraud et al. 2001, 2005).
The sedimentary succession of the NGP consists of upper Palaeozoic to lower Cretaceous siliciclastics and upper Cretaceous‒Palaeogene carbonates (Said 1962; Abdallah and Adindani 1963; Bandel and Kuss 1987; Kuss et al. 2000). The thickness of this succession gradually decreases towards the south, confirming deposition during marine transgressions that came mainly from the north (Klitzsch 1990; Klitzsch et al. 1990; Kuss and Bachmann 1996; Kora 1998).
The NGP rises significantly above the lowland of Wadi Araba in the south and gently slopes towards Wadi Ghewibba in the north (Fig. 1b). In general, the Northern and Southern Galala plateaus are NE–SW oriented, representing a major branch of the Syrian Arc structure in the northern part of the Eastern Desert of Egypt (e.g., Said 1962). This arc consists of a belt of complex uplifts and domal anticlines that can be traced from Syria to the central part of the Western Desert of Egypt, passing through northern Sinai and the northern Eastern Desert (Fig. 1a) (Said 1962; Meshref 1990; Shahar 1994). Folding and/or uplift of the Syrian Arc were active during the Late Cretaceous (post-Cenomanian times) and extended into Early Palaeogene (Meshref 1990; Moustafa 2002, 2013; Höntzsch et al. 2011), associated with the closure of the Neo-Tethys Ocean (Lüning et al. 1998; Stampfli et al. 2001). Furthermore, upper Palaeozoic rocks of the eastern side of the NGP are folded and faulted against the Cretaceous‒Eocene succession, forming several horsts and grabens (Fig. 1c) (e.g., Said 1962; Abdallah and Adindani 1963).
Material and methods
In the measured Carboniferous‒Permian succession, stratigraphical, sedimentological and palaeontological data were gathered through detailed field descriptions of each bed. Sedimentary textures, sedimentary structures, nature of bedding and bedding contacts, faunal and/or floral content, and the lateral variability for each bed have been documented along an area of about 750 m to the northwest and to the southeast of Wadi Aheimer. A total of 123 rock samples have been collected from each characteristic facies. Ichnological field observations were concentrated on the identification of ichnogenera and document their distribution along the exposed succession. The size of the trace fossils and their physical interrelationships (e.g., interpenetrating, intercalated or isolated occurrences) were noted. Careful investigation has also been made to the ichnological aspects that allow the ichnofabric characterisation, such as trace fossil assemblage, tiering, cross-cutting relationships and the Ichnofabric Index. In addition, representative rock samples (27 samples) containing some of these trace fossils have been collected for detailed investigations. They were marked with arrows to indicate in-situ orientations within the bed and photographed.
In the laboratory, standard thin-sections of 57 rock samples were examined for their petrography. In addition, a total of 11 moderately to badly-preserved brachiopod specimens were treated with a dilute hydrogen peroxide solution to remove adhering matrix for identification. Furthermore, some moderately preserved plant remains in five rock samples were identified. All rock and fossil samples are housed in the collections of the Department of Geology, Faculty of Science, Alexandria University. Numbers of rock samples are prefixed by WA for the Wadi Aheimer section.
Stratigraphy
Lithostratigraphy
Wadi Aheimer exposes the stratotype section of the upper Palaeozoic Aheimer Formation (Abdallah and Adindani 1963). This formation is exclusively recorded in outcrops from the NGP in the western side of the Gulf of Suez region (Tables 1, 2). In the study area, the Aheimer Formation is overlain unconformably either by the Permo‒Triassic red beds of the Qiseib Formation or by the lower Cretaceous pebbly sandstones of the Malha Formation (Said 1962; Abdallah and Adindani 1963). Southward, the Aheimer Formation has been considered to overlie conformably or to interfinger with the Abu Darag Formation (Awad and Said 1966; Klitzsch 1990) or with the Rod El Hamal Formation (Said 1971). In fact, these three formations are characterised by unexposed bases. Therefore, the exact superposition of these formations is uncertain.
The Aheimer Formation consists of sandstones and siltstones alternating with fossiliferous shale and dolomite beds, commonly in repetitive cycles (Figs. 2, 3). It attains a thickness of about 250 m. Noteworthy is the great change in thickness of this formation from place to place within short distances. The studied succession is herein subdivided into four informal rock units, from oldest: unit I, II, III and IV (Figs. 3, 4a). These units are correlated with some lithostratigraphic schemes that have been proposed to describe the upper Palaeozoic deposits in the eastern side of the NGP (Table 2).
Unit I
This unit consists of intercalated shale, clayey and/or dolomitic siltstone, sandstone and sandy dolomite (Figs. 3, 4b). It represents the oldest unit exposed in the study area, attaining a thickness of about 40 m. Southward, near Bir Abu Darag, it reaches a thickness of about 60 m (e.g., Abdallah and Adindani 1963). The basal 32 m of this unit is composed of dark grey shale (organic-rich in parts), intercalated with reddish brown ferruginous hard siltstone, sandstone and sandy dolomite interbeds (Fig. 4b). The thickness of each bed ranges from about 0.1 to 0.5 m, increasing upward, with sharp contacts. Up-section (between 32 and 40 m), variegated fissile shale dominates, alternating with laminated, wave-rippled, thin-bedded siltstones and fine-grained sandstones (Figs. 3, 4c).
Unit I is the richest fossil-bearing horizon encountered in the study area. Sediments are highly burrowed (Fig. 3), represented by simple vertical and deep burrows (see ‘Ichnological analysis’ below). In addition, poorly-preserved crinoid columnals, bivalves, small gastropods, brachiopods (Antiquatonia sp., Rhynchopora sp.; Fig. 4h, j) and bryozoans occur (Fig. 3). Furthermore, intervals enriched in microfauna are also recorded. Agglutinated foraminifera are the most common microfaunal element, followed by microgranular forms. Ostracod and conodont elements, in contrast, play only a minor role. Based on different macro- and microfossil assemblages, several studies support a Late Pennsylvanian (Westphalian‒Stephanian) age for this unit (Omara and Vangerow 1965; Said and Eissa 1969; Herbig and Kuss 1988; Klitzsch 1990; Kora 1998; present study). Unit I is correlated with the lower Lophophyllidium-bearing shale of Abdallah and Adindani (1963), the lower part of unit I of Abd El-Azeam (1990), the lower member of Kora and Mansour (1992) and sequence I of El-Barkooky (1994) (Table 2).
It is worthy of mention that the lower Lophophyllidium-bearing shale unit was introduced by Abdallah and Adindani (1963) in an area about 8 km to the SW of the Wadi Aheimer succession based on the apparently abundant horn coral Lophophyllidium. However, our field observations of this unit at the area west of the Gulf of Suez in the Wadi Aheimer and Abu Darag areas (for about 30 km SE of the Wadi Aheimer succession) reveal that the occurrence of this rugose coral is remarkably scarce. Therefore, the pertinence of this nomenclature is debatable. Instead, the characteristic feature throughout this unit is the high abundance of elongate vertical burrows of the Tisoa ichnotaxon (see ‘Ichnological analysis’ below). Therefore, we inclined to designate this unit as “the Tisoa-bearing unit” to characterise the latest Carboniferous sediments and mark the Carboniferous/Permian boundary particularly in the study type section of the Aheimer Formation.
Unit II
Unit II (about 50 m thick) is dominated by cross-bedded sandstones and siltstones, unconformably overlying unit I (Figs. 3, 4c). The base of this unit is characterised by a lens of massive sandstone (about 0.5 m thick) and underlies a thin light grey hard laminated kaolinitic siltstone layer (about 1.0 m thick). Above (41.5‒58 m) is yellow, thick, moderately cemented, tabular and trough cross-bedded pebbly sandstone (Fig. 4c), containing clasts up to 7 cm long near the base. Pebbles vary in size laterally and are mostly composed of mono- and polycrystalline quartz. In addition, the amount of pebbles gradually decreases in the upper part of this unit. Between 58 and 60 m, sandstone sediments become finer and grade to siltstone with plant remains (Fig. 4d). This siltstone layer is followed by a reddish yellow, moderately cemented, tabular and trough cross-bedded, medium- to fine-grained sandstone bed (60‒80 m). The uppermost part of unit II (80‒90 m) consists of sandstone, siltstone and shale interbeds (Fig. 3).
Noteworthy is the complete absence of marine macro- and microfossils in unit II. However, some plant remains (Calamites sp.) and rare trace fossils are recorded (Figs. 3, 4d). Calamites lived during the Carboniferous and Permian periods (e.g., Rafferty 2011). Based on the sharp stratigraphic discontinuity with the underlying unit I (Figs. 3, 4c; see ‘Sequence stratigraphy’ below), an Early Permian age could be suggested to unit II. This unit is correlated with the lower part of the middle limestone-sandstone of Abdallah and Adindani (1963), the upper part of unit I of Abd El-Azeam (1990), the lower part of the middle member of Kora and Mansour (1992) and the lower part of sequence II of El-Barkooky (1994) (Table 2).
Unit III
This unit attains a thickness of about 82 m (interval between 90 and 172 m; Fig. 3), and consists of yellowish white to reddish sandstone, light grey to white partly kaolinitic siltstone and variegated shale interbeds (Figs. 3, 4e). This succession is intercalated with two to three thin brownish ferruginous hard highly fractured and fossiliferous sandy dolomite beds that increase in number near the top of the unit (up to seven ledges; Fig. 4l). Sandstone layers are partly rippled laminated (Fig. 4e), fractured, hummocky cross-bedded, fine- to medium-grained, highly burrowed and dolomitic in parts (Fig. 3). The thickness of some beds in this unit varies greatly. Some ferruginous truncation surfaces also occur, representing erosive or omission surfaces that can be traced laterally.
Shale layers in the lower part of unit III, between 115 and 119 m, contain some plant remains (Figs. 3, 4f). The identified samples include Ginkgo-like fossil leaves that can be traced back to the Early Permian (e.g., Florin 1949). In addition, dolomite layers are fossiliferous with some thin-shelled brachiopods (e.g., Composita sp., Dielasma sp., Linoproductus sp., Rhipidomella sp.; Fig. 4g, i), crinoid fragments, bryozoans (Fig. 4k) and fusulinid foraminifer, confirming likewise an Early Permian age (cf. Kora and Mansour 1992; Kora 1998). Furthermore, sandstone beds are highly burrowed with abundant trace fossils (Fig. 3; see ‘Ichnological analysis’ below). This unit is correlated with the upper part of the middle limestone-sandstone of Abdallah and Adindani (1963), unit II of Abd El-Azeam (1990), the upper part of the middle member of Kora and Mansour (1992) and the upper part of sequence II of El-Barkooky (1994) (Table 2).
Unit IV
This unit is mainly composed of sandstone, siltstone and shale, attaining a thickness of about 78 m (interval between 172 and 250 m; Fig. 3). The lower part of this unit (172‒210 m) consists of yellowish, fine- to medium-grained, planar to trough cross-bedded sandstones (Fig. 3), having remarkable bulging steep slopes (Fig. 4m) and laterally extending throughout the study area. The upper part (interval between 210 and 250 m) consists of shales, cross-bedded sandstones, and siltstones. In addition, some dolomitic sandstone lenses are sporadically recorded (Fig. 3). The basal dark grey shale (210‒218 m) overlies the lower bulging sand body (Fig. 3) and is non-fossiliferous, organic rich and gypsiferous. Above are very thin interbeds of red siltstone and very fine sandstone. The upper part of shale (about 32 m thick) is sandier and exhibits ripples and lenticular bedding. In the topmost part of unit IV, sandstone sediments yield rare brachiopod imprints and trace fossils (Fig. 3).
In Wadi Araba, about 60 km to the south of the study area, Lejal-Nicol (1990) described a typical Permian flora from deposits of the upper member of the Aheimer Formation. In addition, early Permian fossil algae have been recorded from these sediments (Omran and Khalifa 1988). Furthermore, overlying the Aheimer Formation, the lower multi-coloured clastic part of the Qiseib Formation (Abdallab and Adindani 1963) contains fossil tree trunks and other plant remains, documenting an Early Permian age (see Klitzsch 1990). In view of the rare occurrence of trace and macrofossils and based on the stratigraphic continuity with the underlying unit III, an Early Permian age could be extrapolated to include also unit IV of the studied Aheimer Formation. This unit is correlated with the upper sandstone, shale and silts of Abdallah and Adindani (1963), unit III of Abd El-Azeam (1990), the upper member of Kora and Mansour (1992) and sequence III of El-Barkooky (1994) (Table 2).
Sequence stratigraphy
Three well defined unconformities have been recognized within the study succession. These surfaces define four 3rd-order depositional sequences that are named according to the area of definition (depositional sequence Northern Galala, DS NG 1‒4; Fig. 5). The sequence-stratigraphic stacking patterns of facies, key surfaces and systems tracts have been recognized by several criteria based on the works of Ernst et al. (1996), Coe (2003), Embry (2009), Catuneanu et al. (2011) and Catuneanu (2017, 2019).
Depositional sequence NG 1
DS NG 1 is of Late Carboniferous age and comprises the complete unit I (the Tisoa-bearing unit) of the Aheimer Formation (Fig. 5a). Deposits consist of repetitive cycles of highly burrowed shale, siltstone, sandstone, and sandy dolomite interbeds, confirming the occurrence of an aggrading shelf (Van Wagoner et al. 1990) that is characterised by a shallowing and coarsening-upward vertical stacking pattern of facies (Figs. 5a, b, 6a). The recorded aggradational parasequence sets that are truncated by a sequence boundary document the occurrence of an early highstand systems tract (HST) (Catuneanu 2006). In view of the exposure, only the HST of this sequence is present (Fig. 5a). The sequence boundary capping DS NG 1, SB1, is described in the next section.
Depositional sequence NG 2
DS NG 2 comprises the basal lower Permian sediments of the studied succession. It includes the entire unit II and the lower part of unit III (Fig. 5a), attaining a thickness of about 80 m. The lower part of this sequence consists of cross-bedded pebbly sandstones and kaolinitic siltstone and is followed by mudstone and sandstone with fossiliferous dolomite interbeds (Fig. 5a, b). The basal sequence boundary of DS NG 2, SB1, is represented by the erosional contact of pebbly and coarse-grained sandstone strata atop the aggradational parasequences sets of DS NG 1 (Fig. 5b). The following lowstand systems tract (LST) consists of fluvial multi-storey channel facies associated with four fining-upward units of a high to low energy fluvial system (Figs. 5a, b, 6b). These sediments are considered as an incised valley fill based on its erosional base and rapid lateral thickness changes (Catuneanu et al. 2011). Quartz pebbles in the lower part of this LST may indicate transport within the flooded valley. The transgressive systems tract (TST) starts with a thin lag deposit of pebbly sandstone, representing a transgressive ravinement surface (Nummedal and Swift 1987) that is defined as an erosional surface resulting from wave scouring (i.e., wave ravinement surfaces) (Swift 1975) or tidal scouring (tidal ravinement surface) (Allen and Posamentier 1993) during transgression (Fig. 6c). This ts surface is followed by a retrogradational stacking pattern of deepening-upward cycles of marine facies (Figs. 5a, 6c). The highly fossiliferous dolomite layer characterises the maximum flooding surface (mfs) that is also confirmed by the occurrence of fining-upward cycles below and coarsening-upward cycles above (Fig. 6c). The HST consists of five coarsening-upward cycles of mudstone and sandstone interbeds (Fig. 6d).
Depositional sequence NG 3
DS NG 3 is represented by the upper part of unit III of the Aheimer Formation (about 50 m thick; Fig. 5a). It consists of sandstone, shale, mudstone, fossiliferous dolomitic sandstone and fossiliferous sandy dolomite interbeds. The basal sequence boundary SB2 is marked by karstification, palaeosols and extensive omission surface (Fig. 5c). Along this surface, marine strata of the topmost part of DS NG 2 are truncated by a thin (2‒3 m thick) fining-upward cycle of unfossiliferous sandstone and mudstone of fluvial origin, representing part of the LST (Figs. 5c, 6e). In contrast to the first sequence boundary (SB1), SB2 is almost flat with low relief and non-conglomeratic (Fig. 5c), supporting the absence of an incised valley here.
The following TST is characterised by seven fining-upward marine cycles of highly burrowed and fossiliferous dolomitic sandstone, fossiliferous sandy dolomite and shale (Fig. 5a) deposited mostly in shoreface environments. Thus, the surface between the LST and TST represents a marine flooding surface (i.e., ts), recording a deepening event. It may be considered as a transgressive ravinement surface (cf. Nummedal and Swift 1987). Laterally, the transgressive surface (ts) of DS NG 3 is amalgamated with SB2 due to the lack of accommodation space during deposition of the LST (Fig. 6f). The lower part of this TST is characterised by the predominance of siliciclastic facies whereas carbonate deposits become increasingly common in the upper part (Fig. 5a).
The mfs of DS NG 3 is represented by the seventh dolomite layer (Fig. 5a). Based on the presence of an open-marine macrofauna and trace fossils, this carbonate layer represents the deepest part of this sequence and indicates the maximum transgression of the shoreline. This layer can clearly be distinguished and easily correlated across the study area. The HST consists of four cycles of fossiliferous sandy dolomite and heterolithic cross-bedded sandstone/mudstone facies that are followed by hummocky cross-stratified sandstone facies and ripple laminated sandstone/siltstone facies, confirming a shallowing-upward trend towards the end of the HST (Fig. 5a, d).
Depositional sequence NG 4
This depositional sequence attains a thickness of about 78 m, and comprises the entire unit IV (Fig. 5a). The recorded HST of DS NG 3 is truncated by the fluvial sandstone of DS NG 4, forming an extensive omission surface and representing the third sequence boundary (SB3) (Fig. 5d). The lower part of this sequence consists mainly of tabular and trough cross-bedded sandstones that are composed of clean sands (Figs. 4h, 5a). The stacking pattern of facies in this interval shows a fining-upward of the LST that resulted from braided streams (Fig. 6g). This stacking pattern of facies containing the highest energy fluvial systems is comparable to the lowstand topset of a downstream-controlled sequence (Catuneanu et al. 2011; Catuneanu 2019). The LST deposits are overlain by gypsiferous and organic-rich shale and red siltstone interbeds (about 8 m thick), representing deposition in restricted estuarine conditions. Therefore, the base of these estuarine facies is selected to define the transgressive surface (ts) of this sequence (Figs. 5a, 6g).
The upper part of this sequence consists of shale, siltstone and sandstone interbeds and is characterised by flat and rippled lamination, ripples and lenticular bedding. The stacking pattern of facies in this part shows an aggrading to a retrograding pattern, which might be the result of a general transgressive phase. These TST facies mostly reflect upper to middle shoreface depositional settings.
Regionally, the four recorded upper Carboniferous‒lower Permian sequences in the studied section are considered as a part of the first-order mega-sequence of the Arabian plate (AP5) of Sharland et al. (2001). The lower boundary of this AP5 sequence is marked by the 'Hercynian unconformity' or the 'pre-Unayzah unconformity' (Sharland et al. 2001). The recorded sequences can also be correlated with the late Carboniferous second-order sequence of the Algerian Saharan Platform (Fekirine and Abdallah 1998), and with the upper part of the Carboniferous (NA4) and the lower part of the Permian (NA5) second-order sequence of North Africa (Carr 2002). The sequence boundary (SB5) between NA4 and NA5 represents the Carboniferous/Permian Hercynian Unconformity (Carr 2002).
Microfacies analysis
Microfacies analysis of the upper Carboniferous–lower Permian Aheimer Formation is based on investigation of rock thin-sections, supplemented by field observations of some features such as lithology, bedding, sedimentary structures and trace and body fossil content. Detailed petrographic analysis of the studied upper Palaeozoic succession has revealed a predominance of siliciclastic, with few carbonate (mainly dolomite) facies (Table 3). In siliciclastic facies, bioclasts are rare or nearly absent. In contrast, bioclasts are common in carbonate facies and are represented by crinoids, echinoids, brachiopods, bryozoans, benthic foraminifera and algae (Table 3; Figs. 7, 8, 9).
Facies analysis reveals 11 (micro-) facies types (FT1–FT11). All these facies types (nine siliciclastic and two carbonate) are described and interpreted. Based on similar attributes, the recorded 11 facies types are grouped into four different facies associations (FA1–FA4), representing a wide spectrum of depositional environments. They include: (FA1) intertidal to shallow subtidal facies association, (FA2) fluvial channel fill/overbank facies association, (FA3) upper shoreface to offshore transition facies association, and (FA4) interdistributary bay and/or restricted estuarine facies association (Table 3).
Ichnological analysis
Trace fossil assemblages
Trace fossils occur throughout the studied stratigraphic succession. They are highly abundant in units I and III (Fig. 3). The recorded ichnofossil assemblages are composed of horizontal, vertical, and sub-vertical traces attributable to the activity of a variety of crustaceans, polychaetes, bivalves and arthropods. At least 26 ichnotaxa, belonging to 23 ichnogenera, have been identified (Table 4; Figs. 10, 11, 12, 13). Stratigraphically, nine ichnotaxa (34.6%) were exclusively reported from the upper Carboniferous sediments (i.e., unit I), 12 (46.2%) from the lower Permian unit III, two (7.7%) from the lower Permian unit III and IV, two (7.7%) from unit I and III (i.e., upper Carboniferous‒lower Permian), whereas a single ichnotaxon (3.8%) was reported from the upper Carboniferous‒lower Permian sediments of unit I, II and III. These traces belong to five ethological categories, including domichnia, fodinichnia, cubichnia, pascichnia and repichnion (Table 4).
The mud-dominated sediments of unit I are highly burrowed. Burrows recorded include vertical and sub-vertical dwelling structures of inferred suspension-feeding organisms (e.g., Arenicolites isp., Diplocraterion parallelum, Thalassinoides suevicus, Tisoa siphonalis) and deposit feeders such as Neoeione moniliformis, Neonereites multiserialis, Palaeophycus isp., Planolites isp., Th. suevicus and Treptichnus isp. (Table 4; Figs. 10, 11, 12, 13). Some horizontal traces, including Lockeia siliquaria, Lockeia isp. and Ptychoplasma cf. excelsum are also recorded (Figs. 10e, h, i, 11a, g). Most of the abundant vertical and sub-vertical burrows are long and narrow with sharp to irregular walls, passively filled, and usually paired (Fig 12g‒i, Fig. 13a‒c). It is remarkable that the tops of the abundant U-burrows of Tisoa usually start from the upper surfaces of five siltstone layers recognised in unit I (Figs. 12i, 13b). These burrows may penetrate strata up to 1.5 m depth and thus they could be considered as the longest vertical burrows recorded in this study.
Up-section, a distinctly different ichnocoenosis is recorded within the sandstone-dominated intervals of unit II. It is represented by the monospecific occurrence of a low-density population of Planolites isp. (Fig. 3). In contrast to the underlying strata, unit III is dominated by a characteristic burrowing structure (Fig. 3). Based on the distribution of trace fossils, unit III can be subdivided into two parts. In the lower one (between 90 and 132 m; Fig. 3), the ichno-assemblage comprises abundant Arenituba isp., Palaeophycus isp., Planolites isp., Schaubcylindrichnus freyi, Skolithos isp., Treptichnus isp., Zoophycos isp. and rare Helminthopsis isp. (Figs. 10, 11, 12, 13). This suite of trace fossils reflects the activity of organisms mainly with deposit-feeding and grazing behaviours (Table 4). In comparison to the lower part, the upper part of unit III (between 132 and 172 m; Fig. 3) is characterised by an abundant and diverse ichno-assemblage produced primarily by deposit-feeding organisms in addition to suspension feeders and grazers. It is composed of Circulichnis isp., Cruziana isp., Gordia aff. marina, Palaeophycus isp., Phycodes aff. palmatus, Protovirgularia isp., Rhizocorallium isp., Rusophycus cf. carbonarius, Skolithos linearis, Thalassinoides paradoxicus and Zoophycos isp. (Figs. 10, 11, 12, 13). In particular, Zoophycos appears to be the most common traces in this unit and occurs repeatedly at six different levels within the upper part of unit III (Figs. 3, 13d‒f).
Apparently, the trace fossil assemblage of unit III changes laterally changed to a relatively moderate diversity in a section about 500 m to the southeast of the measured succession. It consists of the fodinichnia Palaeophycus isp., Planolites isp., Rhizocorallum isp., Thalassinoides suevicus and Zoophycos isp. (Table 4; Figs. 10, 11, 12, 13). On the other hand, the sandstone-dominated interval in the topmost part of unit IV is characterised by a rare occurrence of trace fossils. They are represented by traces produced primarily by deposit-feeding organisms, including Rhizocorallum isp. and Zoophycos isp. (Fig. 3).
In general, the aforementioned trace fossils of the Aheimer Formation are exceptionally diverse, abundant, and well preserved. In addition, due to invertebrate macrofossils, namely brachiopods, corals with fragmentary crinoid stems are uncommon and poorly-preserved in the Permo‒Carboniferous strata of the Wadi Aheimer type section. Thus, the ichnological record of the Aheimer Formation is a significant contribution for more complete palaeoecological and palaeoenvironmental reconstructions of the study succession (see below).
Ichnofabric characterisation
According to trace fossil assemblage, tiering, cross-cutting relationships and Ichnofabric Index, the following ichnofabrics could be identified (Fig. 14).
Tisoa ichnofabric (Fig. 14a)
This ichnofabric occurs in the upper Carboniferous unit I (Fig. 3). It is characterised by dark grey shales, intercalated with reddish brown ferruginous hard siltstone, sandstone and sandy dolomite interbeds. Five colonization surfaces have been recognized, indicating discontinuity surfaces, from which the abundant simple, vertical, U-shaped burrows of Tisoa penetrate the underlying strata. It has a sharply defined burrow margin and passive fill. The thin beds are extensively burrowed with an ichnofabric index (sensu Droser and Bottjer 1986) of 3 to 4 (10‒60%). This ichnofabric includes an assemblage composed of diverse ichnofossils. Tisoa siphonalis is the most abundant ichnotaxon and accounts for most of the bioturbation in this ichnofabric (Fig. 14a). Some subordinate ichnotaxa are also recorded. The deepest tier in the sediment was occupied by the ichnogenus Tisoa, whereas Arenicolites, Planolites, Palaeophycus, Lockeia and Ptychoplasma represent the shallow-tier trace fossils. Tisoa-dominated ichnofabrics have been recorded in the middle Bathonian of the Russian platform (Desai et al. 2021) and the upper Jurassic Fensfjord, Sognefjord (Kimmeridgian) and Ula formations (Kimmeridgian‒Tithonian) in the Norwegian Sea (Knaust 2019).
Schaubcylindrichnus ichnofabric (Fig. 14b)
This ichnofabric characterises the lower part of unit III (lower Permian) (Fig. 3). Its host rocks are mostly sandstone, shale, mudstone, fossiliferous dolomitic sandstone and fossiliferous sandy dolomite interbeds. This ichnofabric is characterised by a sparse to low bioturbation intensity (ichnofabric index ranges from 2 to 3). Schaubcylindrichnus is the most abundant ichnofossil with subordinate Arenituba, Palaeophycus, Planolites, Skolithos, Zoophycos and rare Helminthopsis (Fig. 14b). Most of these ichnofossils represent a shallow-tier activity (tiers 1–3; sensu Hasiotis 2012). No colonization surfaces have been recognized. Schaubcylindrichnus-dominated ichnofabrics have been recorded in the lower‒upper Jurassic of Norway (Knaust 2017), the Palaeogene Grumantbyen Formation of Norway (Øygard 2016) and the Miocene Taliao Formation of north-eastern Taiwan (Löwemark and Hong 2006).
Zoophycos ichnofabric (Fig. 14c)
It characterises the upper part of unit III of the Aheimer Formation. This ichnofabric is associated with sandstone, shale, mudstone, fossiliferous dolomitic sandstone and fossiliferous sandy dolomite interbeds (Fig. 3). Bioturbation intensity is moderate (ichnofabric index ranges from 3 to 4) and diversity of the trace fossil association is moderate to high. No colonization surfaces have been recognized. Zoophycos appears to be the most common trace in this ichnofabric, associated with several other ichnotaxa (Fig. 14c). Generally, the ichnofossils in this ichnofabric, with higher abundance and moderate diversity, are mainly composed of trails on the bedding plane and a few fodinichnia near the bedding plane, locally crosscutting each other. Most trace fossils (about 70%) such as Phycodes, Cruziana, Rusophycus, Planolites and Palaeophycus occupy the shallower horizons (tiers 1–3). However, Zoophycos represents the shallow-middle tier of this ichnofabric. In addition, very shallow tiers to superficial traces (e.g., Gordia and Circulichnis) are common and produced almost no disturbance of the primary fabric. The Zoophycos ichnofabrics are a common component of the distal expression of the Cruziana ichnofacies in many Palaeozoic successions, e.g., the Chefar El Ahmar Formation (Devonian) of Algeria (Bouchemla et al. 2021), the middle Permian of Oman (Knaust 2009), the lower Permian Taiyuan Formation of central China (Hu and Qi 2000) and the Hongguleleng Formation (Devonian–Carboniferous transition) of western Junggar, NW China (Fan and Gong 2016).
Discussion
The present study differs from others in integrating, for the first time, different stratigraphical, sedimentological and ichnological information in order to arrive at an accurate insight into the palaeoenvironmental characterisation of the Aheimer Formation. The additional granularity seems to be as a result of the inclusion of ichnological data (Table 4), confirming the finer resolution of the present study.
Palaeoenvironments and palaeoecology
Outcrops in the NGP, including the type section studied, are evidently of younger Carboniferous (Westphalian‒Stephanian) and Early Permian ages (Tables 1, 2). These siliciclastic-dominated deposits reflect a marginal depositional site (Tables 3, 4; Fig. 15). The close proximity of the study area to the shoreline (Fig. 1d) is inferred due to the indications of a strong siliciclastic input (Fig. 3). Lithofacies analyses have revealed that this formation was laid down across a relatively wide spectrum of depositional environments, including shallow subtidal, prograding shoreline and fluvial conditions (Table 3), reflecting different stacking patterns of facies in the available accommodation space (Fig. 5a). As mentioned above, the studied succession is subdivided into four 3rd-order sequences. The most important depositional features and environmental parameters governing the distribution of trace fossils, macrofauna and flora are discussed below.
Depositional sequence NG 1 (upper carboniferous)
The HST deposits of this sequence are represented by a single facies association (FA1), including two facies types (FT1 and FT2) (Table 3; Figs. 3, 5a). These fine-grained siliciclastic and dolomite facies types show a marine environment, ranging from intertidal to shallow subtidal settings (Fig. 15). The tidal effect throughout deposition is supported by the occurrence of highly ferruginous sandstone/shale couplets, and the existence of wave-ripples, cross-lamination, and mudstone drapes in sandstone (e.g., Buatois and Mángano 2003). The pattern of facies repetition with nearly equal thickness of sets of strata (Figs. 4b, 5a, b, 6a) confirms an aggrading shelf with equal rates of accommodation and sedimentation (Van Wagoner et al. 1990). In addition, the cyclical thickening and thinning may reflect differences in tidal current energy during neap-spring tidal fluctuations (Kvale et al. 1989; Kvale and Archer 1990).
The occurrence of organic-rich fissile shale may suggest a partially restricted shallow subtidal marine environment with a low to moderate rate of sedimentation (e.g., Pemberton et al. 1992). In addition, the recorded small-scale oscillation ripples and combined flow ripples also indicate periods of standing water and wave modification. This restricted condition helped in reducing the wave action (i.e., low to moderate water energy), and consequently, permits accumulation of organic material in bottom sediments. In these restricted environments, which are characterised by the increase of nutrient supply in the water column and fine-grained sediment, the seafloor and bottom sediments may become oxygen-deficient (i.e., dysoxic conditions; cf. Jarvis et al. 1988; Koutsoukos et al. 1990; Fürsich et al. 2012). These conditions may be also documented by the low to moderate species diversity of macrofossils (mainly brachiopods and crinoids) and microfossils (mainly agglutinated and microgranular benthic foraminifera). In addition, the near absence of infaunal elements may also reflect these dysoxic conditions (cf. Oschmann 1993; Fürsich et al. 2012). In these stressed conditions, the Tisoa trace maker may burrow deeply into anoxic sediments for deriving energy via chemosymbiosis and consequently produce extraordinary depths (Knaust 2019; present study).
As was mentioned, sediments of DS NG 1 are intensively burrowed (Table 4; Fig. 3). The abundant traces of suspension-feeding organisms support at least moderate water energy that keeps organic nutrients in suspension (i.e., a low to moderate rate of sedimentation). At the same time, this level of water energy permits the accumulation of food particles for different deposit-feeding trace makers of several ichnotaxa. The occurrence of large-diameter Thalassinoides points to a nutrient-rich and well-oxygenated water column along with low- to moderate-energy conditions (e.g., Abdel-Fattah et al. 2016; El-Sabbagh et al. 2017; Vinn et al. 2020). However, shrimp-produced Thalassinoides had a broader range of salinity tolerance, ranging well into environments of low salinity (e.g., Swinbanks and Luternauer 1987). Horizontal burrows of Treptichnus ichnotaxon suggest low-energy conditions on the marine shelf (Buatois et al. 2013). The latter is also confirmed by the absence of the more basinal marine expressions (e.g., Rhizocorallium and Zoophycos) and/or high-energy proximal suites (e.g., Skolithos). Diplocraterion ichnospecies have been found in tidal flats and estuaries (e.g., Buatois and Mángano 2011; Gingras et al. 2012a). In these aspects, their producer is considered as an opportunistic species (e.g., r-strategist) that thrived in stressful brackish-water conditions (Knaust 2017). The latter is also confirmed by the occurrence of some agglutinated genera as Ammobaculites, Trochammina and Reophax (Kureshy 1966; Armstrong and Brasier 2005).
Based on the works of Seilacher (1964, 1967a, b) and Frey and Seilacher (1980), all of the recorded ichnogenera correspond to a firmground suite of the Glossifungites Ichnofacies, representing colonization of exhumed firm but unlithified substrates, and greatly resembling the intermediate energy firmground suites of MacEachern et al. (2007b). Although suites attributable to the Glossifungites Ichnofacies occur in a wide range of environments (Hayward 1976; Frey and Seilacher 1980; Savrda 1991; MacEachern et al. 1992a, b; Raychaudhuri et al. 1992; MacEachern and Burton 2000; Gingras et al. 2002a, b; Bann et al. 2004; Dasgupta and Buatois 2012), the trace fossil suite in this ichnofacies, dominated with long, narrow vertical tubes, and usually paired, is common in nearshore environments, particularly in intertidal sediments (e.g., Rhoads 1967; Zonneveld et al. 2001). These findings are consistent with our results. The trace makers require the substrate to be exhumed by mechanical removal of loose unconsolidated overburden in order to reach the firm substrate (e.g., MacEachern et al. 1992a, b; Buatois and Mángano 2011). Consequently, this leads to the development of a discontinuity surface, i.e., short-lived omission (e.g., MacEachern et al. 1992a; Pemberton et al. 2001). In the study area, a total of five autogenic Glossifungites Ichnofacies-demarcated siltstone surfaces (sensu Abdel-Fattah et al. 2016) were recognized in sediments of DS NG 1. After subaerial exhumation and/or submarine erosion, the colonization stage of the discontinuity surface by firmground trace makers is performed during periods of marine conditions (i.e., a hiatus in deposition). Subsequently, passive filling of the burrows is completed during an ensuing depositional episodes and burial of the firmground suite.
Depositional sequence NG 2 (lower Permian)
As was mentioned, this sequence consists of three systems tracts: LST, TST and HST, comprising the entire unit II and the lower part of unit III (Fig. 5a). The LST sediments are represented by a single facies association (FA2) that includes two facies types (FT3 and FT4) (Table 3; Fig. 3). The presence of trough and planar cross-bedding, fining-upward cycles and an erosive lower boundary supports these stacked deposits as low-sinuosity braided channels (Postma 1990; Galloway and Hobday 1996; Miall 1996). Pebbly and coarse-grained sandstones are interpreted as channel fills deposited by tractive currents, whereas the fine-grained sandstone and siltstone are deposited during the stage of falling flow velocity of the flood on the channel banks (Dalrymple et al. 1990; Miall 1996). In addition, kaolinitic siltstones could be related to changes in climate to a wet period and retrogradational time (Kämpf and Schwertmann 1983).
The large and rounded exotic quartz pebbles and gravels characterise the lower part of the LST of this sequence seem to be derived from quartz veins occurring within the Precambrian basement and transported northward for a long distance. It is worth mentioning that, within the Palaeozoic succession of the northern part of the Eastern Desert of Egypt, similar large pebbles are only recorded in the basal part of the Cambrian sandstone of the Araba Formation at Somr El Qaa (around 28°13'N and 32° 22'E) (Klitzsch et al. 1990). The latest Carboniferous and earliest Permian tectonic instability played an important role in the influx of these coarse clastics with high rates of deposition (e.g., Klitzsch 1990; Klitzsch et al. 1990).
Within these LST sediments, pith casts of Calamites are recorded (Fig. 4d). Calamites grew to 20 m tall, standing mostly along the sandy banks of rivers (Rafferty 2011). In addition, a distinctly different ichnocoenosis is represented within this unit by the monospecific occurrence of a small population of Planolites isp. (Fig. 3), which, in this context, indicates a stressed, opportunistic colony (Ekdale 1985; Bromley 1996). Freshwater discharge was conducive to limit biogenic activity, resulting in reduced trace fossil diversity and sparse burrowing (e.g., Bhattacharya and MacEachern 2009). In addition, the absence of marine micro- and macro- fossils in sediments of this LST confirms these environmental conditions (Fig. 15).
In general, sediments of both TST and HST of DS NG 2 consist of sandstone, siltstone, mudstone and dolomite interbeds, representing mainly the third facies association (FA3) and including five facies types (FT5‒FT9; Figs. 3, 5a). Furthermore, these sediments are characterised by abundant sedimentary structures, highly burrowed and fossiliferous with micro- and macro- fossils (Tables 3, 4; Fig. 3). These results confirm depositional palaeoenvironments ranging from upper shoreface to the offshore transition (Fig. 15). Sandstones with large-scale tabular-planar cross-bedding, trough cross-bedding and symmetrical wave ripples can be deposited throughout the upper shoreface (Clifton 2006). Sandstones and siltstones showing large-scale hummocky cross stratification and oscillation ripples mark the lower to middle shoreface environment (Hunter and Clifton 1982; Clifton 2006). The amalgamation of the oscillatory motion from waves and storm-generated currents are assumed to produce hummocky cross-stratification (Harms et al. 1982; Swift et al.1983; Duke et al. 1991). Burrowed and fossiliferous dolomite with crinoids, brachiopods, bivalves, foraminifera and bryozoan skeletal fragments suggest normal-marine environments ranging from lower shoreface to offshore transition (Table 3). The latter is also confirmed by the lower level of burrowing and the paucity of physical sedimentary structures in the mudstone sediments, documenting deposition below fair-weather wave-base in a quiet-water environment (i.e., offshore transition) (Leckie and Walker 1982; Rosenthal and Walker 1987; MacEachern and Pemberton 1992).
Sediments of the upper part of the HST of this depositional sequence are burrowed with a characteristic suite of trace fossils (Figs. 3, 5a, 15), confirming the activity of varied producers that mainly performed different trophic behaviours. This part (between 110 and 118 m; Figs. 3, 5a) contains abundant Palaeophycus isp., Planolites isp., Thalassinoides paradoxicus, Skolithos isp. and Zoophycos isp., reflecting the activity of deposit (fodinichnia) and suspension (domichnia) feeders (Table 4). Although Zoophycos is a common ichnotaxon in deep marine waters of the Mesozoic and later (Ekdale and Berger 1978; Bottjer et al. 1987; Vinn et al. 2020), Palaeozoic Zoophycos occurs in nearshore deposits (e.g., Osgood and Szmuc 1972; Yurewicz 1977; Vinn and Toom 2015; Bouchemla et al. 2021). Skolithos is typically marine in origin (e.g., Trewin and McNamara 1995). It is a common indicator of relatively high energy, shallow-water, nearshore to marginal-marine environments (e.g., Desjardins et al. 2010; Vinn and Wilson 2013; Knaust 2017). Palaeophycus occurs in various palaeoenvironmental marine settings (Frey and Pemberton 1991; Löwemark and Nara 2010; Toom et al. 2019), including shoreface and offshore deposits (Knaust 2017). Consequently, this trace fossil assemblage occurring in the upper part of the HST of DS NG 2 is interpreted as the shallow-marine (middle to lower shoreface) proximal Cruziana Ichnofacies (e.g., Seilacher 1967a, b).
Depositional sequence NG 3 (lower Permian)
Similar to the underlying sequence, DS NG 3 consists of three systems tracts: LST, TST and HST, comprising the upper part of unit III (Fig. 15). The LST sediments are devoid of any marine micro- or macro- fossils. However, plant remains and rare traces of Helminthopsis isp. have been found (Fig. 3). The recorded Ginkgo-like fossil leaves (Fig. 4f) represent a terrestrial plant, which prefers a warm, humid, open-canopy and a well-drained environment (Lin et al. 2022). Helminthopsis is a facies-crossing ichnotaxon, common in both marine and non-marine settings (e.g., Pemberton et al. 2001). Their producer, probably polychaete annelids, occurs in brackish to fully marine environments (Bromley 1996; Buatois et al. 1998).
Sediments of both TST and HST of DS NG 3 represent the second and the third facies associations (FA2 and FA3, respectively), including seven facies types (FT3‒FT9; Figs. 3, 5a). In addition, these sediments are characterised by moderately abundant sedimentary structures, highly burrowed and highly fossiliferous with macrofossils (Tables 3, 4; Fig. 3), documenting depositional environments ranging from upper shoreface to offshore transition (Fig. 15).
The heterolithic nature of the facies indicates sedimentation in alternating suspension fallout and bed-loads within a low-energy setting below wave base (i.e., deposition in the lower shoreface environment) (Hunter et al. 1979; Leckie and Walker 1982; MacEachern and Pemberton 1992). Sediments of the TST, in particular, are intensively burrowed with a high ichnodiversity (Figs. 3, 5a, 15). These ichnotaxa have been produced primarily by deposit-feeding organisms in addition to suspension feeders and grazers (Table 4). Cruziana co-occurs with Rusophycus and they are mainly related to shallow-water environments (e.g., Fillion and Pickerill 1990; Seilacher 2007; Vinn 2014; Vinn and Toom 2016). Phycodes likewise is commonly recorded in shallow-marine environments (Han and Pickerill 1994). Palaeophycus is regarded as a eurybathic trace fossil recorded in diverse environments (e.g., Pemberton et al. 2001). Circulichnis is known in marine and non-marine sediments (Fillion and Pickerill 1984; Uchman and Rattazzi 2019). Gordia is a facies-crossing form that occurs in both marine and non-marine settings (Gaigalas and Uchman 2004), including shallow and deep-water marine deposits (Miller and Knox 1985). Schaubcylindrichnus occurs in a wide range of environments, particularly in lower shoreface deposits (Frey and Howard 1985, 1990). Rhizocorallium occurs in nearshore, shelf and deep-marine sediments (e.g., Mángano et al. 2002; Knaust 2017). It represents a common constituent of transgressive systems tracts (e.g., Knaust 1998; MacEachern et al. 2012).
In general, the presence of a diversified trace fossil assemblage, produced primarily by deposit feeders in low- to moderate-energy conditions along with a moderate rate of sedimentation in nutrient-rich sediments, as well as the water column, suggests a typical proximal-archetypal Cruziana Ichnofacies (e.g., MacEachern et al. 1999, 2007a). In general, the presence of fully marine trace fossils (e.g., Cruziana, Rausophycus, Rhizocorallium) with almost homogeneous distribution suggests relatively stable and low-stress conditions (Gingras et al. 2012b; MacEachern et al. 2010). However, the occurrence of abundant Zoophycos in about six levels within the upper part of the TST of DS NG 3 (Figs. 3, 15) may indicate an episodic depletion of oxygen on the seafloor, i.e., dysoxic to anoxic seafloor conditions. Ekdale and Mason (1988) mentioned that fodinichnia-dominated associations (e.g., Zoophycos) occur where bottom water is oxic to dysoxic and the interstitial water is anoxic. In general, sediments accumulated in oxygen-poor depositional environments commonly contain trace fossils that have been produced by low-oxygen-tolerant deposit-feeding organisms (e.g., Bromley and Ekdale 1984; Savrda and Bottjer 1986). Furthermore, the oxygen-controlled trace-fossil model of Ekdale and Mason (1988) suggests that the decrease of oxygen concentration of the interstitial water parallels a transition from trace-fossil associations dominated by dwelling traces of suspension feeders (i.e., domichnia) to trace-fossil associations dominated by deposit-feeding structures (i.e., fodinichnia). These observations are in accordance with our results.
Depositional sequence NG 4 (lower Permian)
This sequence consists of several facies types, representing two systems tracts: LST and TST (Figs. 3, 5, 15). This greatly varied microfacies and abundant sedimentary structures document different depositional settings, ranging from fluvial (FT3) in the entire of LST, restricted estuary (FT11) in the basal part of the TST, and shoreface (FT5, FT8, FT9) in the upper part of the TST, and confirming different stacking pattern of facies in the available accommodation space (Fig. 15).
The LST starts with fluvial deposition represented by planar to trough cross-bedded sandstones, and confirming that braided streams dominated the area. Deposition of clean sand can be interpreted as stream bedload continuously cutting their banks, leaving no chance for floodplain fines to be preserved (e.g., Miall 1985, 1993; Galloway and Hobday 1996). The highest degree of channel amalgamation is recognized at the base of fluvial depositional sequences and is caused by a combination of low rates of floodplain aggradation, high rates of lateral channel migration, and high rates of avulsion (Catuneanu et al. 2011; Catuneanu 2017, 2019).
In the basal part of the TST, the organic-rich mudstones are devoid of any marine micro- or macro- fossils. The overlying very thin interbeds of red siltstone and fine-grained sandstone may indicate the presence of subaerial exposures and oxidation (Miall 1985, 1996; Retallack 2001). Consequently, these facies may be deposited in restricted estuaries with alternating low- and moderate-energy conditions (Prothero and Schwab 1996). On the other hand, sandstone and siltstone sediments in the upper part of the TST are characterised by flat and ripple lamination, wave-rippled thin beds and low-angle cross lamination with rare brachiopod imprints and other marine ichnofauna, documenting deposition in the upper to middle shoreface environment (Fig. 15) (Hunter and Clifton 1982; Clifton 2006).
Regional correlations
In Egypt, similar depositional settings have been recorded at several outcrops on the western side of the Gulf of Suez (Tables 1, 2). In the subsurface of the Gulf of Suez region, the Aheimer Formation is correlated with the upper part of the Nubia “B member” of the oil companies' classification (e.g., Hermina et al. 1983). In addition, time-equivalent rocks are likewise known from the subsurface of the northern part of the Western Desert (the Safi Formation; e.g., Keeley 1989). On the eastern side of the Gulf of Suez, in contrast, the absence of the upper Carboniferous‒lower Permian Aheimer Formation reflects local uplift caused by tectonic deformation in conjunction with the Hercynian Orogeny (Kora 1984, 1998; Klitzsch 1990; Klitzsch et al. 1990; Issawi et al. 1999; Guiraud et al. 2001, 2005). The Permo‒Carboniferous sediments as well as the older deposits were consequently removed by erosion. In general, all these upper Carboniferous‒lower Permian successions may represent the last major invasion of the Palaeo-Tethys Ocean into the northern part of Egypt during Palaeozoic times (Bandel and Kuss 1987; Keeley 1989; Klitzsch 1990; Klitzsch et al. 1990).
On the other hand, the studied upper Carboniferous‒lower Permian Aheimer Formation can be regionally correlated with the Assedjefar, Dembaba and Tiguenrourine formations of western Libya (Bellini and Massa 1980). The upper part of the Aheimer Formation can be correlated with the lower Permian Saad Formation of southern Israel (Zaslavskaya et at. 1995). In Syria, equivalent Permo-Carboniferous sediments have been described as the Heil Formation (Al-Youssef and Ayed 1992). Equivalent deposits were also recorded in central Saudi Arabia (the Unayzah Formation; Al-Laboun 1987) and in Oman (the Al Khlata and Gharif formations; Levell et al. 1988).
Carboniferous–Permian glaciations
The late Carboniferous‒ early Permian glaciations in Gondwana were diachronous and affected North Africa and the Middle East region (e.g., Le Heron et al. 2009 and references therein). With the exception of some examples of glacially-related deposits in the Gilf El Kebir region of SW Egypt, i.e., the eastern Sahara (Klitzsch 1983, 1990), all other upper Carboniferous‒Permian glacial deposits are only well established in Oman, Yemen and Saudi Arabia (Braakman et al. 1982; Al Husseini 2004; Le Heron et al. 2009). In these regions, ice sheets and glaciers were mainly concentrated in tectonically uplifted areas at active plate boundaries, i.e., Hercynian uplift (Eyles 1993; Al Husseini 2004).
In the Gilf El Kebir region of SW Egypt, and adjacent to the Libyan border, Klitzsch (1983) described poorly sorted sediments unconformably overlying a Devonian–Stephanian fluvio-deltaic succession. This unit, the Wadi Malik Formation (sensu Klitzsch 1990), is overlain by Jurassic lacustrine deposits. Le Heron et al. (2009, p. 68) stated that “a glacial origin for these poorly sorted deposits remains plausible but has not been subsequently substantiated”. Consequently, further fieldwork is required to confirm the glacial origin for these sediments.
No previous studies have identified any evidence for the late Carboniferous‒ early Permian glaciations in the northern parts of Egypt. However, El-Noamani and Tahoun (2019) reported that the palaeofloral communities recovered from the subsurface upper Palaeozoic Safi Formation in the west Beni Suef Basin of the northern Western Desert of Egypt may confirm a significant effect of a glacial climate. They identified two palaeofloral communities. The first one is represented by a cold climate low- and wet- land fern community. The second palaeocommunity includes an upland palaeoflora that is mainly developed under the influence of lacustrine flooding resulting from minor deglaciation events.
In fact, the reliability of the influence of the late Carboniferous‒Permian glacial-interglacial cycles on the studied sedimentary succession in Wadi Aheimer requires further investigation. However, the occurrence of lithologically repetitive successions containing organic-rich fissile shales in the HST of the DS NG 1 (Figs. 3, 4b, 5a, b, 6a) may be attributed to the effect of the late Carboniferous interglacial cycles, representing shallow glaciomarine organic-rich sediments accumulating in topographically depressed areas during transgression (sensu Lüning et al. 2000). In addition, in the Mid-Continent region of North America during the Permo‒Carboniferous period, the growth and decay of Gondwanan ice sheets caused large eustatic sea-level fluctuations, resulting in deposition of lithologically repetitive successions. These cyclical sequences include thin core shale deposits, which are enriched in organic matter, trace metals and authigenic phosphate, confirming deposition during glacio-eustatic highstands that resulted in oxygen-deficient bottom waters in this mid-continental sea in that region (Heckel 1986, 1991; Algeo et al. 2004). Alternatively, these black shales in the HST of the studied section may be interpreted as sediments deposited along the maximum flooding surface (MFS) (cf. Armstrong et al. 2005).
In the studied lower Permian succession, as mentioned above, sediments of the LST of the DS NG 2, 3 and 4 (Figs. 3, 5) represent sediments of several braided streams, suggesting that these deposits may have accumulated in a glaciofluvial setting (see Le Heron et al. 2009). In this glacio-terrestrial setting, deposition occurs on a plain that is characterised by interconnected incisions and braided systems (Duller et al. 2008; Le Heron et al. 2009). These observations are in accordance with our results.
Conclusions
The type section of the Permo‒Carboniferous Aheimer Formation in the eastern foot slopes of the Northern Galala Plateau, west of the Gulf of Suez, has been studied by integrating stratigraphical, sedimentological and trace fossil data. Three Permian sequence boundaries (SB1‒3) bound four 3rd-order depositional sequences, including the upper Carboniferous DS NG 1, and the lower Permian DS NG 2‒4. Litho- and bio- facies development shows a strong relationship to the interpreted sequence architecture. Four different facies associations, comprising 11 facies types, represent a wide spectrum of depositional palaeoenvironments ranging from fluvial, estuarine, intertidal, shallow subtidal, shoreface to offshore transitional settings.
The abundant and diverse late Carboniferous‒early Permian ichno-assemblages are composed of horizontal, vertical and sub-vertical traces, confirming the activity of a variety of crustaceans, polychaetes, bivalves and arthropods. At least 26 ichnotaxa have been identified, representing suites of the Glossifungites, proximal Cruziana and proximal-archetypal Cruziana ichnofacies. Ichnofabric analysis revealed three distinct types, including Tisoa, Schaubcylindrichnus and Zoophycos ichnofabrics.
The presence of fully marine trace and body fossils with almost homogeneous distribution supports relatively stable and low-stress conditions. In contrast, the trophic structure of some other assemblages reflects the influence of particular environmental parameters, including substrate consistency, bathymetry, water energy, productivity, rate of sedimentation, salinity and oxygen availability. The integrated results indicate that the sequences were formed during an interval dominated by different perturbations that resulted in a wide spectrum of depositional features. Moreover, evidence for the Carboniferous–Permian glaciation is tentatively established in North Egypt but requires further investigation.
Data availability
No supplementary material available for this article.
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Acknowledgements
We are grateful to Chris Boyd (IPC Canada) and an anonymous reviewer for their constructive comments and to the Editor-in-Chief, Maurice Tucker (University of Bristol), for his insightful suggestions that immensely improved the manuscript. We are indebted to Murray Gingras (University of Alberta) for advice, fruitful comments in the early manuscript, and for providing one of us (Magdy El Hedeny) with access to his publication database. Thanks are also due to Anju Saxena (Birbal Sahni Institute of Palaeosciences) for the help with identification of some plant remains. We extend our thanks to Mohamed Rashwan and Mohamed Abdelmaksoud (Alexandria University) for their helps during part of the fieldwork.
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El-Refaiy, A.A., El-Sabbagh, A.M., Hedeny, M.M.E. et al. Stratigraphical, microfacies, and ichnological characteristics and depositional environments of the Permo‒Carboniferous Aheimer Formation, western side of the Gulf of Suez, Egypt. Facies 69, 8 (2023). https://doi.org/10.1007/s10347-023-00666-7
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DOI: https://doi.org/10.1007/s10347-023-00666-7