Hostname: page-component-cd9895bd7-dzt6s Total loading time: 0 Render date: 2024-12-26T15:27:28.438Z Has data issue: false hasContentIssue false

Early biomineralization and exceptional preservation of the first thrombolite reefs with archaeocyaths in the lower Cambrian of the western Anti-Atlas, Morocco

Published online by Cambridge University Press:  18 October 2022

Abdelfattah Azizi*
Affiliation:
Département de Géologie, Faculté des Sciences et Techniques, Université Cadi-Ayyad, BP 549, 40000 Marrakesh, Morocco
Abderrazak El Albani
Affiliation:
Laboratoire IC2MP 7285 CNRS-INSU, Université de Poitiers, 86022 Poitiers, France
Asmaa El Bakhouche
Affiliation:
Département de Géologie, Faculté des Sciences et Techniques, Université Cadi-Ayyad, BP 549, 40000 Marrakesh, Morocco
Olev Vinn
Affiliation:
Department of Geology, University of Tartu, Ravila 14A, 50411 Tartu, Estonia
Olabode M. Bankole
Affiliation:
Laboratoire IC2MP 7285 CNRS-INSU, Université de Poitiers, 86022 Poitiers, France
Claude Fontaine
Affiliation:
Laboratoire IC2MP 7285 CNRS-INSU, Université de Poitiers, 86022 Poitiers, France
Ahmid Hafid
Affiliation:
Département de Géologie, Faculté des Sciences et Techniques, Université Cadi-Ayyad, BP 549, 40000 Marrakesh, Morocco
Khaoula Kouraiss
Affiliation:
Département de Géologie, Faculté des Sciences et Techniques, Université Cadi-Ayyad, BP 549, 40000 Marrakesh, Morocco
Khadija El Hariri
Affiliation:
Département de Géologie, Faculté des Sciences et Techniques, Université Cadi-Ayyad, BP 549, 40000 Marrakesh, Morocco
*
Author for correspondence: A. Azizi, Email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Thrombolite reefs with archaeocyaths are common in the subtidal limestones of the lower Cambrian in the western Anti-Atlas of Morocco. The Igoudine Formation of the Tata Group recorded the first replacement of the microbial consortium (stromatolite-dominated) by thrombolite reefs with archaeocyaths and shelly metazoans. In order to better understand the role of the microbial community in the formation of thrombolite reefs with archaeocyaths across this critical transition, the macro-, micro- and ultra-fabric of thrombolites have been studied in detail. Three major components are identified within the first thrombolytic reef: archaeocyaths, calcimicrobes and micritic matrix. The studied thrombolites are typically dominated by the calcimicrobe Renalcis with subordinate Epiphyton and Girvanella. Scanning electron microscopy of the dark micrite of the Renalcis chambers showed amorphous translucent sheet-like structures interpreted as extracellular polymeric substances, closely associated with organominerals including nanoglobules and polyhedrons. Exceptionally well-preserved Renalcis chambers contain bacterial fossils similar to those described in modern microbialites, including microspherical coccoid fossils and filamentous bacteria that are either spaced or in close associations forming colonies. These organomineralization-related features suggest a bacterial origin for the Renalcis calcimicrobe. The matrices between the Renalcis chambers consist predominantly of clotted peloidal micrite. Mineralization of Renalcis microframes may involve two major biomineralization processes: (1) replacement of organic matter by organominerals resulting from anaerobic degradation of extracellular polymeric substances and bacterial sheaths and (2) encrustation of bacterial sheaths and extracellular polymeric substances due to increasing alkalinity of the microenvironment. These mechanisms played a crucial role in the early diagenetic cementation and preservation of the studied reefs.

Type
Original Article
Copyright
© The Author(s), 2022. Published by Cambridge University Press

1. Introduction

Thrombolites are benthic microbial carbonates recognized by their patchy mottled/clotted structures with no internal lamination (Aiken, Reference Aiken1967; Tang et al. Reference Tang, Shi, Jiang, Pei and Zhang2012) and are composed of calcimicrobes, micrite and peloids (Riding, Reference Riding2008). Kershaw et al. (Reference Kershaw, Li, Crasquin-Soleau, Feng, Mu, Collin, Reynolds and Guo2007) applied the term digitate dendrolite to Permian–Triassic boundary microbialites in Sichuan, China. However, Riding (Reference Riding, Reitner, Quéric and Arp2011) presented a plausible argument that a dendrolitic form seen in vertical section may also be classified as a thrombolite because in transverse section the branched structure appears as clots on a cut surface (Riding, Reference Riding, Reitner, Quéric and Arp2011; Kershaw et al. Reference Kershaw, Zhang and Li2021). Thrombolites are found globally in various modern depositional environments such as open subtidal settings (Planavsky & Ginsburg, Reference Planavsky and Ginsburg2009; Myshrall et al. Reference Myshrall, Mobberley, Green, Visscher, Havemann, Reid and Foster2010; Mobberley et al. Reference Mobberley, Ortega and Foster2012), freshwater (Laval et al. Reference Laval, Cady, Pollack, McKay, Bird, Grotzinger, Ford and Bohm2000; Gischler et al. Reference Gischler, Gibson and Oschmann2008), alkaline (Arp et al. Reference Arp, Reimer and Reitner2003) and hypersaline (Puckett et al. Reference Puckett, McNeal, Kirkland, Corley and Ezell2011) lakes, and hot springs (Campbell et al. Reference Campbell, Francis, Collins, Gregory, Campbell, Greinert and Aharon2008). Early works suggested that the clotted fabrics of thrombolites may have resulted from the destruction of stromatolitic laminae by metazoans or diagenesis (Hofmann, Reference Hofmann1973; Walter & Heys, Reference Walter and Heys1985). Research on modern thrombolites in the Bahamas (Highborne Cay; Myshrall et al. Reference Myshrall, Mobberley, Green, Visscher, Havemann, Reid and Foster2010), Australia (Shark Bay; Jahnert & Collins, Reference Jahnert and Collins2012) and Kuwait (Arabian Gulf; AlShuaibi et al. Reference AlShuaibi, Khalaf and Al-Zamel2015) have improved our knowledge of these kinds of calcareous microbialites and also confirmed their primary biogenic origin. Similar to other microbialites, thrombolites are formed from complex interactions between microbial communities and the surrounding waters, whereas microbially induced calcification and/or trapping and binding of sediments are the most important processes involved in their growth and expansion (Burne & Moore, Reference Burne and Moore1987; Riding, Reference Riding2000; Planavsky & Ginsburg, Reference Planavsky and Ginsburg2009; Jahnert & Collins, Reference Jahnert and Collins2012).

The lower Cambrian deposits in Morocco are widely exposed in the Anti-Atlas belt and High Atlas Mountains (Álvaro et al. Reference Álvaro, Benziane, Thomas, Walsh and Yazidi2014). During this period, the marine platform of the Anti-Atlas was part of the northern margin of the Gondwana supercontinent. Microbial reefs (dominated by stromatolites) remained unaffected until the early Cambrian Stage 3 (Atdabanian). During the formation of the Tiout Member (upper unit of the Igoudine Formation) an important palaeoecological event took place, characterized by the replacement of the microbial consortium (stromatolite-dominated) by thrombolites and shelly metazoans (Hupé, Reference Hupé1960; Schmitt & Monninger, Reference Schmitt, Monninger and Flügel1977; Schmitt, Reference Schmitt1979; Destombes et al. Reference Destombes, Hollard, Willefert and Holland1985; Debrenne & Debrenne, Reference Debrenne and Debrenne1995; Álvaro & Clausen, Reference Álvaro and Clausen2006; Álvaro & Debrenne, Reference Álvaro and Debrenne2010; Clausen et al. Reference Clausen, Álvaro and Zamora2014). Several authors have mentioned the first episode of thrombolite reefs with archaeocyaths in the lower Cambrian (Series 2) Tiout Member in the western Anti-Atlas (Benssaou & Hamoumi, Reference Benssaou and Hamoumi2004; Álvaro & Debrenne, Reference Álvaro and Debrenne2010; Álvaro et al. Reference Álvaro, Benziane, Thomas, Walsh and Yazidi2014); however, the detailed study and interpretation of this event is still lacking. The current work is focused on the details of the structures, mineralogy and geochemistry, providing a genesis model for the first thrombolite reef complex containing archaeocyaths in the lower Cambrian of Morocco.

2. Geological setting and stratigraphy

The Anti-Atlas Mountains are a c. 1300 km long NE–SW-trending belt in the central part of Morocco (Fig. 1a, b). The southern slope of the Anti-Atlas contains well-exposed Palaeozoic sedimentary successions resting on the Precambrian Pan-African orogen (Destombes et al. Reference Destombes, Hollard, Willefert and Holland1985; Geyer & Landing, Reference Geyer and Landing1995). It comprises a ∼1800 m thick mixed siliciclastic-carbonate deposit on the north Gondwana margin (western Anti-Atlas, Morocco) directly deposited on the ∼2000 m thick volcanic and volcaniclastic rocks of the Ediacaran Ouarzazate Supergroup (577–560 Ma) (Thomas et al. Reference Thomas, Fekkak, Ennih, Errami, Loughlin, Gresse, Chevallier and Liégeois2004; Gasquet et al. Reference Gasquet, Ennih, Liégéois, Soulaimani, Michard, Michard, Saddiqi, Chalouan and Frizon de Lamotte2008; Walsh et al. Reference Walsh, Benziane, Aleinikoff, Harrison, Yazidi, Burton, Quick and Saadane2012; Fig. 1b). This Ediacaran–Cambrian succession accumulated on the thermally subsiding continental shelf (Maloof et al. Reference Maloof, Schrag, Crowley and Bowring2005) in the upper part of the eastern Anti-Atlas platform. The Tata Group is well exposed in the Taroudant province, and has previously been described in the Tiout, Amouslek and Tazemmourt areas (Álvaro et al. Reference Álvaro, Ezzouhairi, Vennin, Ribeiro, Clausen, Charif, Ait Ayad and Moreira2006), and within the Issafen and Fouanou synclines. The ∼1000 m thick Tata Group consists of four formations: Igoudine, Amouslek, Issafen and Asrir (Fig. 1c). The basal Igoudine and Amouslek deposits represent carbonate-dominated environments such as peritidal flats and ooid shoals. The upper part of the Igoudine Formation has been described only in the Tiout area as the Tiout Member (Álvaro et al. Reference Álvaro, Ezzouhairi, Vennin, Ribeiro, Clausen, Charif, Ait Ayad and Moreira2006), containing the boundary interval where the microbial consortium (stromatolite-dominated) sediments were first replaced by thrombolite reefs with archaeocyaths and shelly metazoans (Álvaro et al. Reference Álvaro, Benziane, Thomas, Walsh and Yazidi2014). The thickness of the overlying Amouslek Formation ranges between 20 and 220 m and consists of variegated shales with interbedded limestones.

Fig. 1. (a) Location map of the Anti-Atlas of Morocco. (b) Simplified geological sketch showing the distribution of the Precambrian–Cambrian outcrops in the Anti-Atlas Mountains (drawn after Saadi et al. Reference Saadi, Hilali, Bensaïd, Boudda and Dahmani1983). (c) Stratigraphic section through the lower Cambrian of the Fouanou syncline. (d) Detailed lithostratigraphic section of the studied horizon in the Fouanou syncline (the diameters of archaeocyath cups were measured within the levels L1 and L2).

The Tommotian–Atdabanian boundary interval is widely exposed in the western Anti-Atlas (Fouanou syncline). One characteristic section comprising the Igoudine and Amouslek formations has been logged by us (Fig. 1d). The stratigraphic succession in this area comprises similar sedimentary facies to those described within the type sections of the Tiout and Amouslek areas (Álvaro et al. Reference Álvaro, Ezzouhairi, Vennin, Ribeiro, Clausen, Charif, Ait Ayad and Moreira2006; Álvaro & Debrenne, Reference Álvaro and Debrenne2010).

The lowermost unit of Igoudine Formation (∼40 m thick) consists of massive black oolithic limestones, with rare dome-shaped stromatolites, symmetric ripples and cross-stratifications. In the middle unit (∼35 m thick) dominated by stratified dolostones, displaying crinkled dome-shaped and stratiform stromatolites, wave ripples and rare cross-stratifications, horizons shows slumped and faulted stromatolites. Based on the sedimentary facies, both previous units were deposited in upper subtidal to intertidal environments. The upper unit of the Igoudine Formation formed by massive bedded oolitic limestone (‘black oolitic limestone facies’ of Monninger, Reference Monninger1979 and Schmitt, Reference Schmitt1979) is characterized by the emergence of small-sized archaeocyaths, Adtabanian in age, including Dictyocyathus, Erismacoscinus and Agastrocyathus. Some beds exhibit cross-stratifications and rare wave ripples and erosion surfaces. The latter unit is overlain by the Tiout Member dominated by dendritic thrombolites with archaeocyaths, which is the first microbial archaeocyathan reef barrier of the Anti-Atlas. Thrombolite–archaeocyathan reefs are characterized by successive reef-growth phases delimited by surfaces of reef-growth interruption, which suggest that this reef barrier may have formed under low-energy conditions with occasional high-energy events, generating erosion surfaces. The latter conditions can occur between the middle to lower subtidal zone (Jahnert & Collins, Reference Jahnert and Collins2012). The Amouslek Formation consists of variegated shales and siltstones, strongly bioturbated, recording a significant sea-level change from shallow water restricted conditions to deeper open sea conditions (Álvaro & Debrenne, Reference Álvaro and Debrenne2010). The lower part of this unit displays numerous archaeocyathid-bioherms and patch reefs. The upper part consists mainly of shales and fine-grained sandstones with interbedded oolitic limestones, cross-stratifications and wave ripples, recording rhythmic transgressive–regressive depositional sequences.

3. Materials and study methods

Thrombolites were macroscopically examined in the field and in polished slabs in the laboratory. About 70 thin-sections were made for microfacies analyses using an Olympus BH2 polarizing binocular microscope. Platinum-coated and uncoated freshly broken sample fragments were observed for micro/nanostructures using an FEI Teneo Volume Scope scanning electron microscope (SEM), operated at a 5 to 20 kV accelerating voltage and a varying working distance of between 9 and 11 mm, at UFR SFA Pole Biology University of Poitiers, France. Semi-quantitative element analyses of sub-micron-sized spots were determined using an EDAX energy-dispersive X-ray spectrometer (EDS) connected to the SEM at 20 kV and a working distance of 9 mm. The bulk mineral compositions of some thrombolite fragments from the bottom and upper part of the lower reef complex of the Igoudine Formation were determined using a Bruker D8 ADVANCE X-ray diffractometer (CuKα radiation) with operating conditions of 40 kV and 40 mA and a 0.025/s step size.

4. Results

4.a. Thrombolytic reefs with archaeocyaths

4.a.1. Morphology and macrofabric

Thrombolite–archaeocyathan reefs of the Igoudine Formation are characterized by successive reef-growth phases delimited by surfaces of reef-growth interruption (Fig. 2a). The Atdabanian thrombolites of the Igoudine Formation exhibit dark micritic mesoclots in varying sizes and shapes and have maximum diameters ranging between 5 and 20 mm (Fig. 2a, b). The mesoclots are interlaced to form upward-growing dendritic structures (Fig. 2b, c, d). Scattered small-size archaeocyaths are apparent within the studied materials (Fig. 2b, c, d, e, f), but they never exceed 20 % of the total rock volume. Three genera have been identified in the studied horizon including Dictyocyathus, Erismacoscinus and Agastrocyathus. They are usually less than 20 mm in height and preserved in their growth position. The maximum diameters of 150 cups of archaeocyaths measured within two spaced reef cores (Fig. 2b) vary from 1 to 31 mm with a mean of 4.9 mm in the lower level (L1) and from 2 to 47 mm with a mean of 5.6 mm in the upper level (L2) (Fig. 3). Dendritic thrombolites in the lower Cambrian Series 2 of the Founou syncline show well-preserved calcimicrobes such as Renalcis, Epiphyton and Girvanella.

Fig. 2. Macroscopic features of the thrombolite reef with archaeocyaths. (a) Outcrop photograph of thrombolite–archaeocyathan reefs characterized by successive reef-growth phases delimited by surfaces of reef-growth interruption (length of hammer scale is 29.5 cm). (b) Sample slab showing dark grey dendritic mesoclots and light grey matrix with scarce archaeocyaths (Arc). (c, d) Photographs and sketches of longitudinal section showing dendritic clotted fabric growing upwards (red arrows) (Arc – archaeocyath; Es – erosion surface). (e, f) Photographs of transverse sections showing small-sized regular and irregular archaeocyaths (Arc).

Fig. 3. Distribution patterns of the maximum diameter of 150 cups of archaeocyaths measured within two spaced levels (a) L1 and (b) L2 (shown in Fig. 1d). (c) Box-plots of cup diameters in both L1 and L2.

4.a.2. Microscale characteristics

Dendritic thrombolites display well-defined clots containing numerous calcimicrobes, including Renalcis, Epiphyton bundles and subordinate Girvanella tubes visible in thin-sections (Fig. 4a). The Renalcis group is the most abundant dendritic microbial fossil recorded within the studied reefs, consisting of a growing-upward shrub-like array of connected chambers made up of aphanitic micrite (Fig. 4a, b). Micrites, microspar and rare scattered clotted peloids (50 to 100 µm thick) filled the voids separating the Renalcis microframes. The diameters of the chambers range from 0.2 to 1.5 mm, and they commonly occupy the void spaces between the archaeocyath skeletons (Fig. 2c). Calcified microbial thrombolites show a tabular morphology. The Epiphyton calcimicrobe occurs in archaeocyath dominated reefs, encrusting the archaeocyath skeleton (Fig. 4c, d). They are observed as radiating branches consisting of aphanitic micrites and are usually grouped in relatively large colonies (up to 5 mm in diameter) to form a chambered structure (Fig. 4c, d), similar to Renalcis. However, it is difficult to distinguish between both structures in some cases, especially when the filaments are densely connected. Spaced Girvanella tubes are rare and usually separated from the Renalcis and Epiphyton microframes. The light grey matrix surrounding the Renalcis and Epiphyton frameworks consists of micrite and microspar with randomly scattered dark grey micritic peloid-like aggregates with diffuse edges (Fig. 4e, f). Irregular cavities and geopetal structures are common and are filled by greyish microspar or fibrous calcite.

Fig. 4. Microscopic features of thrombolites observed under plane-polarized light. (a, b) Micrographs showing the various forms of Renalcis chambers (R) and Girvanella tubes. (c) Photomicrograph showing Epiphyton chambers (E) attached to archaeocyaths and surrounded by sparitic matrix (Sp). (d) A close-up view of the boxed area in (c) showing Epiphyton chambers with radiating filaments. (e) Photomicrograph of peloidal fabrics in the cryptic space between Renalcis chambers. (f) A close-up view of the boxed area in (e) showing the peloid (P) microspar fabric with a rare cloud of iron oxides (IO) derived from pyrite oxidation.

4.a.3. The nature of the matrix

The matrices between the Renalcis and Epiphyton chambers consist predominantly of clotted micrite and microspar, occurring as scattered poorly sorted peloid ‘grainstone-packstone’ (Fig. 4e, f). Allochthonous fine silt particles, including recognizable quartz and feldspar, are locally incorporated into the thrombolite but are generally scarce and only visible in samples taken beneath the Amouslek Formation shales. The size of the peloids that dominate the matrix microfabric mostly range between 30 and 80 µm. The high-density and coarse-grained peloids are common within the empty spaces between the Renalcis chambers (Fig. 4a, e, f). Some peloids show well-defined boundaries with simple outlines, scattered within the microspar matrix. However, other peloids exhibit irregular forms and occur as clotted aggregates with no well-defined margins. In contrast, the fine-gained peloids are spaced relatively far from the Renalcis microframes (Fig. 4b, e). The Renalcis and Epiphyton chambers also host the fine-grained peloids but in a lower density. A little pyrite also occurs within the matrix under reflected light and is surrounded by a cloud of iron oxides (Fig. 4f).

4.b. Ultra-fabrics of thrombolites

SEM observations of the Renalcis and Epiphyton chambers revealed amorphous translucent sheet-like structures interpreted as extracellular polymeric substances (EPSs) (Arp et al. Reference Arp, Reimer and Reitner2001; Decho et al. Reference Decho, Visscher and Reid2005; Barrett et al. Reference Barrett, Spentzos and Works2009; Mishra et al. Reference Mishra, Fischer and Bäuerle2009; Jones, Reference Jones2011; Zatoń et al. Reference Zatoń, Kremer and Marynowskii2012; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015; Mackey et al. Reference Mackey, Sumner, Hawes, Jungblut, Lawrence, Leidman and Allen2017). Interpreted bacterial remains, pyrite framboids and a closely associated organomineral complex (biologically induced and biologically influenced mineralization), including nanoglobules, polyhedrons and micropeloids, are scattered within the interpreted mineralized EPS matrix.

4.b.1. Extracellular polymeric substances (EPSs)

The EPSs show an amorphous flat and translucent mucus-like matrix (Fig. 5a, b, c) and form a meshwork of subpolygonal pits and walls (1–3 μm thick; Fig. 5a). EDS analyses show that the EPS matrix is composed of C, O, Ca, Si, Mg, Al, K, Cl and rare detectable Fe and S (Fig. 5b, d, e, f). The EPS surface in some areas shows nano-sized cracks (Fig. 6a). Rod-like forms and uniform spherical bodies are similar to those that have been reported in microbialites in many areas and interpreted as bacterial fossils (Perri & Tucker, Reference Perri and Tucker2007; Spadafora et al. Reference Spadafora, Perri, Mckenzie and Vasconcelos2010; Perri et al. Reference Perri, Tucker and Spadafora2012; Shen et al. Reference Shen, Qin, Tenger, Pan, Yang and Bian2017). Bacterial fossils are commonly attached or entombed within the EPS films in the well-preserved samples of Renalcis chambers (Figs 5c, 6b, c, d, e, f). These bacterial cell remains are mainly composed of filamentous and micro-spherical forms and are separated into filamentous tube-like fossils and filamentous rod-like to slightly ellipsoidal-shaped forms based on their different shapes and dimensions. The filamentous tube-like fossils have slightly curved tubes and are either isolated or grouped forming colonies (Figs 5c, 6b, c, d). The filamentous rod-like to slightly ellipsoidal-shaped cells (250–300 nm long and 50 nm wide) are usually found in associations to form colony-like clusters, up to 5 µm in diameter (Fig. 6c, d). Nanoscale SEM observations show the presence of fine granular textures on the surfaces of the possible bacteria fossils (Fig. 6c, d). Micro-spherical forms interpreted as coccoids, with uniform diameters of 600 nm, are grouped in colonies probably associated with irregular organic fragments (Fig. 6c, d).

Fig. 5. Scanning electron microscopy photomicrographs and EDS of microbial structures in the micritic Renalcis chamber. (a) Close-up view of honeycomb-like structure consisting of translucent polygonal pits and walls interpreted as mineralized extracellular polymeric substance (EPS) matrix. (b) EDS spectrum and elemental quantitative data of the spot in (a). (c) EPS relics containing filamentous bacteria (Fb). (d) EDS spectrum and elemental quantitative data of the surface shown in (c) (Pt element resulted from platinum coating). (e, f) Elemental mappings of carbon (C) and calcium (Ca) of the surface in (c).

Fig. 6. Scanning electron microscopy photomicrographs of EPSs and bacterial fossils. (a) EPSs showing nano-sized cracks that possibly result from dehydration of EPS films during early diagenesis. (b) EPS relics coating micrite crystals with filamentous bacterial fossils. (c) Filamentous bacteria (Fb) grouped in a colony. (d) Magnified view of the boxed area in (c) showing the fine granular texture of the surface of bacteria with nano-sized cracks. (e) Grainy surface on possible organic residue. (f) Magnified view of the boxed area in (e) showing the micro-spherical form of possible coccoidal bacteria (CB) covering the surface of organic remains and associated mineralized EPSs.

4.b.2. Organomineral complex

Higher magnification SEM observations of Epiphyton and Renalcis chambers and the clotted peloids show abundant nanoglobules that are 40–80 nm in size (Fig. 7a, b, c, d, e, f) and often fused into clusters to form anhedral polyhedrons of various sizes, depending on the number of the associated aggregates (Fig. 7a, b, c). The polyhedrons coalesce into irregular micrometre-scale micropeloids. The nanoglobules are closely related to EPS relics or clustered on their surfaces (Fig. 7e, f).

Fig. 7. Scanning electron microscopy photomicrographs showing organominerals and detrital micrite in thrombolites. (a) Scattered nanoglobules (Ns) coalesced to form polyhedrons (Po) within EPS films. (b) Magnified view of the boxed area in (a) showing nanoglobules (Ns) and polyhedrons (Po) fused into micropeloids (Pe), closely associated with EPS relics. (c) Nanoglobules (Ns) coalesced to form polyhedrons (Po) and irregular micritic particles. (d) EDS spectrum and elemental quantitative data for nanoglobules (analysed spot (+) in (c)) (Pt element resulted from platinum coating). (e) Nanoglobules closely associated with EPSs and the probable filamentous bacteria (Fb). Nanoglobules (Ns) are visible on EPS flats. (f) Magnified view of the boxed area in (e) showing nanoglobules and nano-cracks resulting from dehydration of EPSs during early diagenesis.

4.b.3. Framboidal pyrite

Pyrite framboids are common in the dark micrite forming the Renalcis and Epiphyton chambers. They are embedded in platy or amorphous EPSs (Fig. 8a, b, c). The diameter of the framboids varies between 4 µm and 40 µm, and they form euhedral (octahedral) microcrystals of 0.5–2 µm in size. The framboidal pyrite entombed in EPS relics contains Fe, S and Ca (Fig. 8d).

Fig. 8. Scanning electron microscopy photomicrographs of pyrite framboids. (a, b) Abundant pyrite framboids (PF) consisting of equidimensional pyrite microcrystals associated with mucus-like EPS relics. (c) Close-up view of the boxed area in (b) showing pyrite framboid. (d) EDS spectrum of pyrite crystal in (c) (+ indicates the position of analysed spot). Fe, S and Ca elements are common in the pyrite crystals.

4.c. Mineralogical composition of thrombolites

Mineralogical compositions of the thrombolite sediments show differences between the bottom and the top of the lower reef complex (Fig. 9a, b). Samples from the basal parts of the section contained mainly carbonate and a small amount of quartz and pyrite (Fig. 9a). However, the upper part of the complex, beneath the Amouslek calcareous shales, is dominated by carbonate and siliciclastic minerals represented by feldspar, mica, silica and a small amount of pyrite (Fig. 9b).

Fig. 9. Bulk rock mineralogical composition of selected samples from (a) the bottom and (b) the top of the lower reef complex of the Igoudine Formation (see Fig. 1d).

5. Discussion

5.a. Components of thrombolite reefs

Early Cambrian microbial reefs containing archaeocyaths have been reported globally (Debrenne et al. Reference Debrenne, Gandin and Rowland1989; Rees et al. Reference Rees, Pratt and Rowell1989; James & Gravestock, Reference James and Gravestock1990; Gandin & Luchinina, Reference Gandin, Luchinina, Barattolo, De Castro and Parente1993; Gandin & Debrenne, Reference Gandin and Debrenne2010). In the Anti-Atlas, stromatolite-dominated microbial reefs remained unaffected until early Cambrian (Atdabanian) time, when thrombolite reefs with archaeocyaths became widespread (Álvaro & Debrenne, Reference Álvaro and Debrenne2010). These changes could be related to sea-level fluctuation, from shallow water restricted to deeper open sea conditions (Álvaro & Debrenne, Reference Álvaro and Debrenne2010).

The scattered small size of the archaeocyaths, their preservation in life position, microbial fabric attachments to Renalcis microframes, encrustation by Epiphyton chambers and a Girvanella crust, as well as their lower abundance (∼20 %) in thrombolite reefs ecosystems, suggest that they were reef dwellers rather than local framework builders. They usually required the presence of microbial elements to form frameworks (Debrenne, Reference Debrenne2007). Archaeocyath–RenalcisEpiphyton reefs occur in low-energy subtidal conditions, mostly from lower subtidal to the outer ramps (Debrenne et al. Reference Debrenne, Gandin and Courjault-Radé2002; Gandin et al. Reference Gandin, Debrenne, Debrenne, Álvaro, Aretz, Boulvain, Munnecke, Vachard and Vennin2007), but they are also present on high-energy platform margins (Kruse et al. Reference Kruse, Zhuravlev and James1995; Riding & Zhuravlev, Reference Riding and Zhuravlev1995). The incorporation of fine-grained sediments into the thrombolite reefs suggests that they formed under low-energy conditions. The presence of erosion surfaces (Fig. 2a, c, d) indicates that reef growth was likely interrupted by episodic storm events. The remarkable change in diameter of archaeocyaths between both horizons L1 and L2 (Fig. 1d) could be related to variations in the chemical and/or hydrodynamic conditions of the environment.

The Igoudine thrombolite reefs are composed of calcimicrobes: Renalcis with subordinate Epiphyton and Girvanella (Fig. 4a, b, c, d). The taxonomic position of Renalcis is controversial, but is it interpreted as red algae, foraminifera and most commonly as cyanobacteria (Mamet, Reference Mamet and Riding1991). Pratt (Reference Pratt1984) interpreted Renalcis as a ‘diagenetic taxa’ resulting from the calcification of coccoid blue-green algae grouped in colonies. However, some authors suggested Renalcis constitutes fossilized biofilm clusters, resulting from the calcification process due to the activity of heterotrophic bacteria (Stephens & Sumner, Reference Stephens and Sumner2002; Turner et al. Reference Turner, James and Narbonne2000). Woo et al. (Reference Woo, Chough and Han2008) and Adachi et al. (Reference Adachi, Nakai, Ezaki and Liu2014) suggested that the Renalcis resulted from diagenetic alteration of Epiphyton chambers based on their similar structures. However, Luchinina (Reference Luchinina2009) suggested that the Renalcis and Epiphyton structures may represent two different steps in the lifecycle of cyanobacteria.

SEM observations of the dark micrite of the Renalcis chambers revealed an amorphous flat and translucent mucus-like matrix (Fig. 5a, b, c, d) interpreted by many authors as EPS biofilms (Arp et al. Reference Arp, Reimer and Reitner2001; Decho et al. Reference Decho, Visscher and Reid2005; Barrett et al. Reference Barrett, Spentzos and Works2009; Mishra et al. Reference Mishra, Fischer and Bäuerle2009; Jones, Reference Jones2011; Zatoń et al. Reference Zatoń, Kremer and Marynowskii2012; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015; Mackey et al. Reference Mackey, Sumner, Hawes, Jungblut, Lawrence, Leidman and Allen2017). Some samples revealed honeycomb-like patterns similar to those observed in modern microbialites (Défarge et al. Reference Défarge, Trichet and Coute1994, Reference Défarge, Trichet, Jaunet, Robert, Tribble and Sansone1996; Dupraz et al. Reference Dupraz, Reid, Braissant, Decho, Norman and Visscher2009; Spadafora et al. Reference Spadafora, Perri, Mckenzie and Vasconcelos2010). Furthermore abundant bacterial fossils have been described including rod-like bacteria and uniform coccoidal bacteria similar to those reported in modern and ancient microbialites (Perri & Tucker, Reference Perri and Tucker2007; Spadafora et al. Reference Spadafora, Perri, Mckenzie and Vasconcelos2010; Perri et al. Reference Perri, Tucker and Spadafora2012; Shen et al. Reference Shen, Qin, Tenger, Pan, Yang and Bian2017) and usually associated with EPSs. However, in many cases, studied fossils of the probable bacteria in our thrombolite reefs are very small and close to the lowest size boundary for the prokaryotes (Crawford, Reference Crawford2007), but such small, usually coccoid, forms have previously been described from recent and fossil microbialites (Spadafora et al. Reference Spadafora, Perri, Mckenzie and Vasconcelos2010; Perri & Spadafora, Reference Perri, Spadafora, Tewari and Seckbach2011).

Our observations suggest a bacterial origin for the Renalcis chambers and support the explanation proposed by Stephens & Sumner (Reference Stephens and Sumner2002) and Turner et al. (Reference Turner, James and Narbonne2000) that suggested a bacterial origin for the Renalcis group, resulting from the calcification process of EPSs and heterotrophic bacteria. The particular forms of Renalcis and Epiphyton can be related to the significant difference in bacterial assemblages involved in their formation.

5.b. Origin of micrite

Micrite is widely used to refer to a rock composed of fine-grained calcite crystals (less than 4 µm) produced in situ or derived from physical transport and deposition of fine particles (Fluegel, Reference Fluegel2010). Microscopic study and higher magnification SEM observations of the micromorphological structures allowed us to recognize the autochthonous micrite deposited in situ through organomineralization of organic compounds and calcification of bacterial sheaths and EPSs.

5.b.1. Biomineralization

The formation of the Igoudine thrombolites is analogous to that recognized in modern microbialites (Dupraz et al. Reference Dupraz, Visscher, Baumgartner and Reid2004; Perri & Spadafora, Reference Perri, Spadafora, Tewari and Seckbach2011) and could involve two major biomineralization processes: (i) replacement of organic matter by biominerals and (ii) calcification or encrustation of bacterial sheaths and EPSs.

Nanoglobules observed in the Igoudine thrombolites are closely associated with EPS relics (Fig. 7a, b, c, e, f), implying their possible origin from anaerobic degradation of EPS biofilms (Aloisi et al. Reference Aloisi, Gloter, Kruger, Wallmann, Guyot and Zuddas2006; Sánchez-Román et al. Reference Sánchez-Román, Vasconcelos, Schmid, Dittrich, McKenzie, Zenobi and Rivadeneyra2008; Perri et al. Reference Perri, Tucker and Spadafora2012; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015). Nanoglobules fuse into variably shaped polyhedrons and micropeloids; similar patterns have been reported in microbial oncoids (Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015). Polyhedrons formed by nanoglobules may have served as primary nuclei for subsequent carbonate crystal growth (Sánchez-Román et al. Reference Sánchez-Román, Vasconcelos, Schmid, Dittrich, McKenzie, Zenobi and Rivadeneyra2008; Spadafora et al. Reference Spadafora, Perri, Mckenzie and Vasconcelos2010; Perri & Spadafora, Reference Perri, Spadafora, Tewari and Seckbach2011; Tang et al. Reference Tang, Chen, Santosh, Zhong and Yang2013; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015). These organominerals can replace the organic part when EPSs and bacterial sheaths have been largely degraded, after the microenvironment become anoxic or dysoxic (Dupraz et al. Reference Dupraz, Visscher, Baumgartner and Reid2004; Spadafora et al. Reference Spadafora, Perri, Mckenzie and Vasconcelos2010; Perri & Spadafora, Reference Perri, Spadafora, Tewari and Seckbach2011; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015). During this process, precipitation of carbonate minerals happened after intensive decomposition of EPSs and bacterial sheaths so that microbial fossils are rarely preserved (Bartley, Reference Bartley1996; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015).

Encrustation of bacterial sheaths and EPSs can occur by increasing alkalinity through photosynthetic removal of CO2 from surrounding waters via photosynthetic prokaryotes and eukaryotic microalgae (Arp et al. Reference Arp, Reimer and Reitner2001, Reference Arp, Reimer and Reitner2003; Obst et al. Reference Obst, Wehrli and Dittrich2009). Bacterial sheaths and EPSs previously secreted by bacteria absorb bivalent cations (Ca2+, Mg2+); the latter decreases the pH of the microenvironment and inhibits carbonate nucleation and precipitation (Dupraz et al. Reference Dupraz, Visscher, Baumgartner and Reid2004; Aloisi et al. Reference Aloisi, Gloter, Kruger, Wallmann, Guyot and Zuddas2006; Braissant et al. Reference Braissant, Decho, Dupraz, Glunk, Przekop and Visscher2007). Such a scenario can favour the preservation of EPSs because encrustation happens before advanced microbial organic matter degradation. For carbonate minerals, the primary environmental factor controlling the biomineralization is pH, and an increase in pH induces the carbonate biomineralization (Zhao et al. Reference Zhao, Yan, Tucker, Han, Zhao, Mao, Peng and Han2020). In the case of possible cyanobacteria, like ancient Girvanella, Epiphyton and Renalcis, photosynthetic uptake of CO2 and/or HCO3 could raise pH in ambient waters (Dupraz et al. Reference Dupraz, Visscher, Baumgartner and Reid2004; Zhao et al. Reference Zhao, Yan, Tucker, Han, Zhao, Mao, Peng and Han2020). On the other hand, heterotrophic bacteria, like sulfate-reducing bacteria at the lower levels of microbial mats, perform ammonification and carbonic anhydrase (CA) catalysis that also raises pH. Moreover, the presence of CA also greatly increases the concentration of bicarbonate in the medium, so that the carbonate minerals reach their saturation state faster (Pan et al. Reference Pan, Zhao, Tucker, Zhou, Jiang, Wang, Zhao, Sun, Han and Yan2019; Zhao et al. Reference Zhao, Yan, Tucker, Han, Zhao, Mao, Peng and Han2020). Increasing alkalinity due to active heterotrophic degradation of organic matter, especially by bacterial sulfate reduction (BSR) communities or other heterotrophic mechanisms, can facilitate mineralization of the bacterial sheaths and EPSs. BSR is active under anoxic to suboxic conditions (Sass et al. Reference Sass, Eschemann, Kuhl, Thar, Sass and Cypionka2002, Reference Sass, Cypionka and Babenzien2006); the bicarbonate (HCO3 ) produced via BSR can increase the alkalinity of the microenvironment (Dupraz et al. Reference Dupraz, Visscher, Baumgartner and Reid2004; Braissant et al. Reference Braissant, Decho, Dupraz, Glunk, Przekop and Visscher2007). The presence of pyrite framboids indicates suboxic to anoxic microenvironments where reduction of sulfate occurred in the water column or close to the sediment/seawater interface (Wilkin & Barnes, Reference Wilkin and Barnes1997; Ohfuji & Rickard, Reference Ohfuji and Rickard2005; Maclean et al. Reference Maclean, Tyliszczak, Gilbert, Zhou, Pray, Onstott and Southam2008; Zhang et al. Reference Zhang, Shi, Jiang, Tang and Wang2015).

5.b.2. Autochthonous peloidal micrite

Although clotted peloidal micrite is very common within the microbialites, numerous interpretations have been proposed to explain the occurrence of peloid clotted fabrics within the microspar. Cayeux (Reference Cayeux1935) suggested that clotted fabrics resulted from partial re-crystallization of peloid grains. However, many authors considered that clotted fabrics are bacterial in origin and formed from in situ precipitation of calcite during degradation of organic matter mediated by heterotrophic bacteria (Reid, Reference Reid1987; Sun & Wright, Reference Sun and Wright1989; Riding, Reference Riding2000). Chafetz (Reference Chafetz1986) and Riding (Reference Riding2002) noted that the clotted microfabric resembles bacterial colonies that form a microfabric of calcified bacterial biofilms. Similar clotted peloidal micrite has been reported from the Holocene reef microbialites in Tahiti, where lipid biomarkers used in laboratory experiments indicated that a sulfate-reducing bacteria-dominated microbial community degrades the organic matter (Heindel et al. Reference Heindel, Birgel, Brunner, Thiel, Westphal, Gischler, Ziegenbalg, Cabioch, Sjövall and Peckmann2012). In the thrombolites, a particular ‘grainstone-like’ peloidal fabric is well developed within the microsparitic matrix (Fig. 4e, f), and higher density and coarse-sized peloids are generally observed close to Renalcis chambers. Micro- and nanoscale SEM observations of the matrix show abundant probable irregular calcified bacterial microcolonies that contain clustered rod-like bacteria with associated calcified EPSs and nanoglobules. The size of the colonies is probably controlled by the number of bacteria involved in their formation and the exposure time to seawater before burial by detrital fractions. The higher density of peloids close to Renalcis microframes can be explained by a large number of bacteria that are regularly detached from these structures to form new biofilms and colonies. The bacteria associated with Renalcis may have consumed its metabolic products.

5.c. Genesis of thrombolites

The Igoudine thrombolitic reefs containing archaeocyaths are interpreted to have developed under favourable conditions for microbial growth such as low siliciclastic input and low hydrodynamic energy with episodic high-energy events. These high-energy events generated numerous surfaces of reef-growth interruption (Fig. 2a, c, d). Under steady conditions, the resulting surfaces were colonized by various microbial populations. EPSs produced by bacteria were accumulated outside the bacterial cells and formed a protective gelatinous film that was used as substrate for attachment by bacterial colonies (Christensen & Characklis, Reference Christensen and Characklis1990). EPSs directly promoted the accretion of microbialites by favouring both mineral precipitation (i.e. biologically induced mineralization) and sediment trapping (Riding, Reference Riding2000). The trapping process can involve simple blockage of grain movement, their adhesion to EPSs and their incorporation (binding) into the mats (Riding, Reference Riding2000). The latter processes were facilitated where microbial mats had irregular surfaces. On the other hand, smooth films with little surface topography can only incorporate fine-grained particles if they are available (Riding, Reference Riding2000). In situ mineral precipitation (autochthonous micrite) is directly promoted through biogenic mineralization of organic compounds and calcification of bacterial sheaths and EPSs (Fig. 10c, d).

Fig. 10. (a, b) Schematic model showing thrombolite growth and (c, d) EPS mineralization process.

Renalcis with subordinate Epiphyton and Girvanella dominate the archaeocyaths of the Igoudine Formation thrombolites. Renalcis boundstones are the main components of the studied thrombolites (Figs 2c, d, 10a, b). Their cryptic growth habitat is comparable to that of modern cryptic reef biofilms. The growth of Renalcis and archaeocyaths was probably synchronous with the influx of fine-grained allochthonous sediments, which are dominantly micrite and fine-grained microsparite. Archaeocyath skeletons are usually attached to microbial microframes (Fig. 2b, c, d), essentially Renalcis dendritic branches, which are in turn encrusted by minor Epiphyton chambers and Girvanella crusts. Small-sized archaeocyaths filled the remaining space between the Renalcis branches (Fig. 2c, d, f), indicating that the available space and the rate of encrustation by the microbial mats likely controlled their growth (Fig. 10a, b). In various examples of early Cambrian thrombolitic reefs containing archaeocyaths, archaeocyaths were considered reef dwellers rather than local framework builders (Debrenne, Reference Debrenne2007). However, they could play vital roles in filling the cavities, decreasing water velocity and accelerating the growth of thrombolite reefs, especially under a low rate of sediment supply.

The rate of multiplication and growth of bacteria probably controlled the size of isolated biofilms scattered within the sediments instead of their exposure time before burial by detrital fractions. Bacterial multiplication and the rate of EPS production was likely controlled by the growth of Renalcis microframes. Nutrients, oxidant supply and the length of surface exposure can play a primary limiting role for bacterial multiplication (Riding, Reference Riding2008). The siliciclastic supply increases upwards in the reef complex and reaches up to 35 % of the total rock volume (Fig. 9b), essentially above the Amouslek calcareous shales. Thereafter, the growth of thrombolites with archaeocyaths of the Igoudine Formation is stopped by the increase in siliciclastic input. The equilibrium between the EPS production and the sedimentation rate of detrital materials in the environment was likely interrupted when the supply of sediments exceeded a threshold value.

6. Conclusion

The first episode of the Atdabanian reef complex in the western Anti-Atlas consists of tabular and dendritic thrombolites. Small regular and irregular archaeocyaths occur in and around the reefs and are composed of three genera: Dictyocyathus, Erismacoscinus and Agastrocyathus. Abundance of archaeocyaths in this horizon does not exceed 20 % of the total rock volume. This suggests that archaeocyaths had a subordinate role in reef-building. The thrombolites containing archaeocyaths are dominated by Renalcis with subordinate Epiphyton and Girvanella. Petrographic study and higher resolution SEM observations of the dark micrite of the Renalcis chambers showed amorphous translucent sheet-like structures interpreted as EPSs, closely associated with organominerals including nanoglobules and polyhedrons. Exceptionally well-preserved Renalcis chambers contain possible bacterial fossils similar to those described in modern microbialites; micro-spherical coccoid fossils and filamentous bacteria coccoid fossils and filamentous tube-like bacteria are observed, isolated or in closely associated colonies, suggesting a bacterial origin for the Renalcis calcimicrobe. The growth and expansion of the Igoudine thrombolites took place under favourable conditions such as low hydrodynamic energy and low siliciclastic input.

Acknowledgements

The authors are grateful to Dr Stephen Kershaw and an anonymous reviewer for their constructive and encouraging comments. Financial support for this study was provided by Cadi Ayyad University Morocco; la Région Nouvelle Aquitaine and the University of Poitiers. The authors are grateful to Françoise Debrenne and Adeline Kerner for identifying the archaeocyaths. Lhoussain Ablouh (Centre des analyses chimique, UCA) and Emile Béré from Pole IMAGE UP, University of Poitiers are acknowledged for SEM and EDS analyses. Mouad Akboub, Idir Elhabib and Mouhssin Elhalim are thanked for their assistance during the fieldwork. We also appreciate Claude and Luis-Marie Bonneval for their warm reception and hospitality in Poitiers. OV was supported by an Estonian Research Council Grant (PRG836), the Sepkoski Grant and a grant by the Institute of Ecology and Earth Sciences, University of Tartu.

Conflict of interest

None.

References

Adachi, N, Nakai, T, Ezaki, Y and Liu, J (2014) Late Early Cambrian archaeocyath reefs in Hubei Province, South China: modes of construction during their period of demise. Facies 60, 703–17.CrossRefGoogle Scholar
Aiken, JD (1967) Classification and environmental significance of cryptalgal limestones and dolomites, with illustrations from the Cambrian and Ordovician of southwestern Alberta. Journal of Sedimentary Research 37, 1163–78.Google Scholar
Aloisi, G, Gloter, A, Kruger, M, Wallmann, K, Guyot, F and Zuddas, P (2006) Nucleation of calcium carbonate on bacterial nanoglobules. Geology 34, 1017–20.CrossRefGoogle Scholar
AlShuaibi, AA, Khalaf, FI and Al-Zamel, A (2015) Calcareous thrombolitic crust on Late Quaternary beachrocks in Kuwait, Arabian Gulf. Arabian Journal of Geosciences 8, 9721–32.CrossRefGoogle Scholar
Álvaro, JJ, Benziane, F, Thomas, R, Walsh, GJ and Yazidi, A (2014) Neoproterozoic–Cambrian stratigraphic framework of the Anti-Atlas and Ouzellagh promontory (High Atlas), Morocco. Journal of African Earth Sciences 98, 1933.CrossRefGoogle Scholar
Álvaro, JJ and Clausen, S (2006) Microbial crusts as indicators of stratigraphic diastems in the Cambrian Micmacca Breccia, Moroccan Atlas. Sedimentary Geology 185, 255–65.CrossRefGoogle Scholar
Álvaro, JJ and Debrenne, F (2010) The Great Atlasian Reef Complex: an early Cambrian subtropical fringing belt that bordered West Gondwana. Palaeogeography, Palaeoclimatology, Palaeoecology 294, 120–32.CrossRefGoogle Scholar
Álvaro, JJ, Ezzouhairi, H, Vennin, E, Ribeiro, ML, Clausen, S, Charif, A, Ait Ayad, N and Moreira, ME (2006) The Early-Cambrian Boho volcano of the El Graara massif, Morocco: petrology, geodynamic setting and coeval sedimentation. Journal of African Earth Sciences 44, 396410.CrossRefGoogle Scholar
Arp, G, Reimer, A and Reitner, J (2001) Photosynthesis-induced biofilm calcification and calcium concentrations in Phanerozoic oceans. Science 292, 1701–4.CrossRefGoogle ScholarPubMed
Arp, G, Reimer, A and Reitner, J (2003) Microbialite formation in seawater of increased alkalinity, Satonda Crater Lake, Indonesia. Journal of Sedimentary Research 73, 105–27.CrossRefGoogle Scholar
Barrett, J, Spentzos, A and Works, C (2009) Isolation and characterization of extracellular polymeric substances from micro-algae Dunaliella salina under salt stress. Bioresource Technology 100, 3382–6.Google Scholar
Bartley, JK (1996) Actualistic taphonomy of cyanobacteria: implications for the Precambrian fossil record. Palaios 11, 571–86.CrossRefGoogle Scholar
Benssaou, M and Hamoumi, N (2004) Les microbialites de l’Anti-Atlas occidental (Maroc): marqueurs stratigraphiques et témoins des changements environnementaux au Cambrien inférieur. Comptes Rendus Geosciences 336, 109–16.CrossRefGoogle Scholar
Braissant, O, Decho, AW, Dupraz, C, Glunk, C, Przekop, KM and Visscher, PT (2007) Exopolymeric substances of sulfate-reducing bacteria: interactions with calcium at alkaline pH and implication for formation of carbonate minerals. Geobiology 5, 401–11.CrossRefGoogle Scholar
Burne, RV and Moore, LS (1987) Microbialites: organosedimentary deposits of benthic microbial communities. Palaios 2, 241–54.CrossRefGoogle Scholar
Campbell, KA, Francis, DA, Collins, M, Gregory, MR, Campbell, SN, Greinert, J and Aharon, P (2008) Hydrocarbon seep-carbonates of a Miocene forearc (East Coast Basin), North Island, New Zealand. Sedimentary Geology 204, 83105.CrossRefGoogle Scholar
Cayeux, M (1935) Les Roches Sédimentaire de France: Roche Carbonatées. Paris: Masson, 463 pp.Google Scholar
Chafetz, HS (1986) Marine peloids; a product of bacterially induced precipitation of calcite Journal of Sedimentary Petrology 56, 812–17.Google Scholar
Christensen, B E and Characklis, W G (1990) Biofilms. New York: Wiley Interscience.Google Scholar
Clausen, S, Álvaro, JJ and Zamora, S (2014) Replacement of benthic communities in two Neoproterozoic–Cambrian subtropical-to-temperate rift basins, High Atlas and Anti-Atlas, Morocco. Journal of African Earth Sciences 98, 7293.CrossRefGoogle Scholar
Crawford, D (2007) Deadly Companions: How Microbes Shaped Our History. Oxford: Oxford University Press.Google Scholar
Debrenne, F (2007) Lower Cambrian archaeocyathan bioconstructions. Comptes Rendus Palevol 6, 519.CrossRefGoogle Scholar
Debrenne, F and Debrenne, M (1995) Archaeocyaths of the lower Cambrian of Morocco. Beringeria Special Issue 2, 121–45.Google Scholar
Debrenne, F, Gandin, A and Courjault-Radé, P (2002) Facies and depositional setting of the Lower Cambrian archeocyath–bearing limestones of southern Montagne Noire (Massif Central, France). Bulletin de la Société géologique de France 173, 533–46.CrossRefGoogle Scholar
Debrenne, F, Gandin, A and Rowland, SM (1989) Lower Cambrian bioconstructions in northwestern Mexico (Sonora). Depositional setting, paleoecology and systematics of archaeocyaths. Geobios 22, 137–95.CrossRefGoogle Scholar
Decho, AW, Visscher, PT and Reid, RP (2005) Production and cycling of natural microbial exopolymers (EPS) within a marine stromatolite. Palaeogeography, Palaeoclimatology, Palaeoecology 219, 7186.CrossRefGoogle Scholar
Défarge, C, Trichet, J and Coute, A (1994) On the appearance of cyanobacterial calcification in modern stromatolites. Sedimentary Geology 94, 1119.CrossRefGoogle Scholar
Défarge, C, Trichet, J, Jaunet, AM, Robert, M, Tribble, J and Sansone, FJ (1996) Texture of microbial sediments revealed by cryo-scanning electron microscopy. Journal of Sedimentary Research 66, 935–47.Google Scholar
Destombes, J, Hollard, H and Willefert, S (1985) Lower Palaeozoic rocks of Morocco. In Lower Palaeozoic Rocks of the World: Lower Palaeozoic of North-Western and West Central Africa: Vol. 4 (ed. Holland, CH), pp. 157–84. Chichester: John Wiley and Sons.Google Scholar
Dupraz, C, Reid, RP, Braissant, O, Decho, AW, Norman, RS and Visscher, PT (2009) Processes of carbonate precipitation in modern microbial mats. Earth-Science Reviews 96, 141–62.CrossRefGoogle Scholar
Dupraz, C, Visscher, PT, Baumgartner, LK and Reid, RP (2004) Microbe–mineral interactions: early carbonate precipitation in a hypersaline lake (Eleuthera Island, Bahamas). Sedimentology 51, 745–65.CrossRefGoogle Scholar
Fluegel, E (2010) Microfacies of Carbonate Rocks. Berlin: Springer, 997 pp.CrossRefGoogle Scholar
Gandin, A and Debrenne, F (2010) Distribution of the archaeocyath–calcimicrobial bioconstructions on the Early Cambrian shelves. Palaeoworld 19, 222–41.CrossRefGoogle Scholar
Gandin, A, Debrenne, F and Debrenne, M (2007) Anatomy of the Early Cambrian ‘La Sentinella’ reef complex, Serra Scoris, SW Sardinia, Italy. In Palaeozoic Reefs and Bioaccumulations: Climatic and Evolutionary Controls (eds Álvaro, JJ, Aretz, M, Boulvain, F, Munnecke, A, Vachard, D and Vennin, E), pp. 2950. Geological Society of London, Special Publication no. 275.Google Scholar
Gandin, A and Luchinina, V (1993) Occurrence and environmental meaning of the Early Cambrian calcareous algae of the Tianheban Formation of China (Yangtze Area). In Studies on Fossil Benthic Algae (eds Barattolo, F, De Castro, P and Parente, M), pp. 211–17. Societá Paleontologica Italiana, Bollettino vol. 1.Google Scholar
Gasquet, D, Ennih, N, Liégéois, JP, Soulaimani, A and Michard, A (2008) The Pan-African Belt. In Continental Evolution: The Geology of Morocco (eds Michard, A, Saddiqi, O, Chalouan, A and Frizon de Lamotte, D), pp. 3364. Berlin: Springer.CrossRefGoogle Scholar
Geyer, G and Landing, E (1995) Morocco’95. The Lower–Middle Cambrian standard of Gondwana. Beringeria Special Issue 2, 1171.Google Scholar
Gischler, E, Gibson, MA and Oschmann, W (2008) Giant Holocene freshwater microbialites, Laguna Bacalar, Quintana Roo, Mexico. Sedimentology 55, 1293–309.CrossRefGoogle Scholar
Heindel, K, Birgel, D, Brunner, B, Thiel, V, Westphal, H, Gischler, E, Ziegenbalg, SB, Cabioch, G, Sjövall, P and Peckmann, J (2012) Post-glacial microbialite formation in coral reefs of the Pacific, Atlantic, and Indian Oceans. Chemical Geology 304, 117–30.CrossRefGoogle Scholar
Hofmann, HJ (1973) Stromatolite characteristics and utility. Earth-Science Review 9, 339–73.CrossRefGoogle Scholar
Hupé, P (1960) Sur le Cambrien inférieur du Maroc. In Report of the 21st International Geological Congress, Norden, Part 8, pp. 7585.Google Scholar
Jahnert, RJ and Collins, LB (2012) Characteristics, distribution and morphogenesis of subtidal microbial systems in Shark Bay, Australia. Marine Geology 303–306, 115–36.CrossRefGoogle Scholar
James, NP and Gravestock, DI (1990) Lower Cambrian shelf and shelf margin buildups, Flinders Ranges, South Australia. Sedimentology 37, 455–80.CrossRefGoogle Scholar
Jones, B (2011) Biogenicity of terrestrial oncoids formed in soil pockets, Cayman Brac, British West Indies. Sedimentary Geology 236, 95108.CrossRefGoogle Scholar
Kershaw, S, Li, Y, Crasquin-Soleau, S, Feng, Q, Mu, X, Collin, P-Y, Reynolds, A and Guo, L (2007) Earliest Triassic microbialites in the South China block and other areas: controls on their growth and distribution. Facies 53, 409–25.CrossRefGoogle Scholar
Kershaw, S, Zhang, T and Li, Y (2021) Calcilobes wangshenghaii n. gen., n. sp., microbial constructor of Permian–Triassic boundary microbialites of South China, and its place in microbialite classification. Facies 67, 28. doi: 10.1007/s10347-021-00636-x.CrossRefGoogle Scholar
Kruse, PD, Zhuravlev, AY and James, NP (1995) Primordial metazoan–calcimicrobial reefs: Tommotian (Early Cambrian) of the Siberian Platform. Palaios 10, 291321.CrossRefGoogle Scholar
Laval, B, Cady, SL, Pollack, JC, McKay, CP, Bird, JS, Grotzinger, JP, Ford, DC and Bohm, HR (2000) Modern freshwater microbialite analogues for ancient dendritic reef structures. Nature 407, 626–9.CrossRefGoogle ScholarPubMed
Luchinina, VA (2009) Remalcis and Epiphyton as different stages in the life cycle of calcareous algae. Paleontological Journal 43, 463–8.CrossRefGoogle Scholar
Mackey, TJ, Sumner, DY, Hawes, I, Jungblut, AD, Lawrence, J, Leidman, S and Allen, B (2017) Increased mud deposition reduces stromatolite complexity. Geology 45, 663–6.CrossRefGoogle Scholar
Maclean, L, Tyliszczak, T, Gilbert, P, Zhou, D, Pray, TJ, Onstott, TC and Southam, G (2008) A high-resolution chemical and structural study of framboidal pyrite formed within a low-temperature bacterial biofilm. Geobiology 6, 471–80.CrossRefGoogle ScholarPubMed
Maloof, AC, Schrag, DP, Crowley, JL and Bowring, SA (2005) An expanded record of Early Cambrian carbon cycling for the Anti-Atlas margin, Morocco. Canadian Journal of Earth Sciences 42, 2195–216.CrossRefGoogle Scholar
Mamet, B (1991) Carboniferous calcareous algae. In Calcareous Algae and Stromatolites (ed. Riding, R), pp. 370451. Berlin: Springer.CrossRefGoogle Scholar
Mishra, A, Fischer, MK and Bäuerle, P (2009) Metal-free organic dyes for dye-sensitized solar cells: from structure: property relationships to design rules. Angewandte Chemie International Edition 48, 2474–99.CrossRefGoogle ScholarPubMed
Mobberley, JM, Ortega, MC and Foster, JS (2012) Comparative microbial diversity analyses of modern marine thrombolitic mats by barcoded pyrosequencing. Environmental Microbiology 14, 82100.CrossRefGoogle ScholarPubMed
Monninger, W (1979) The Section of Tiout (Precambrian/Cambrian Boundary Beds, Anti-Atlas, Morocco): An Environmental Model. Würzburg: Arbeiten aus dem Paläontologischen Institut Würzburg vol. 1, 289 pp.Google Scholar
Myshrall, KL, Mobberley, JM, Green, SJ, Visscher, PT, Havemann, SA, Reid, RP and Foster, JS (2010) Biogeochemical cycling and microbial diversity in the thrombolitic microbialites of Highborne Cay, Bahamas. Geobiology 8, 337–54.CrossRefGoogle ScholarPubMed
Obst, M, Wehrli, B and Dittrich, M (2009) CaCO3 nucleation by cyanobacteria: laboratory evidence for a passive, surface induced mechanism. Geobiology 7, 324–47.CrossRefGoogle ScholarPubMed
Ohfuji, H and Rickard, D (2005) Experimental syntheses of framboids – a review. Earth-Science Reviews 71, 147–70.CrossRefGoogle Scholar
Pan, J, Zhao, H, Tucker, ME, Zhou, J, Jiang, M, Wang, Y, Zhao, Y, Sun, B, Han, Z and Yan, H (2019) Biomineralization of monohydrocalcite induced by the halophile Halomonas smyrnensis WMS-3. Minerals 9, 632. doi: 10.3390/min9100632.CrossRefGoogle Scholar
Perri, E and Spadafora, A (2011) Evidence of microbial biomineralization in modern and ancient stromatolites. In Stromatolites: Interaction of Microbes with Sediments (eds Tewari, V and Seckbach, J), pp. 631–49. Dordrecht: Springer-Verlag.CrossRefGoogle Scholar
Perri, E and Tucker, ME (2007) Bacterial fossils and microbial dolomite in Triassic stromatolites. Geology 35, 207–10.CrossRefGoogle Scholar
Perri, E, Tucker, ME and Spadafora, A (2012) Carbonate organo-mineral micro- and ultrastructures in sub-fossil stromatolites: Marion Lake, South Australia. Geobiology 10, 105–17.CrossRefGoogle ScholarPubMed
Planavsky, N and Ginsburg, RN (2009) Taphonomy of modern marine Bahamian microbialites. Palaios 24, 524.CrossRefGoogle Scholar
Pratt, BR (1984) Epiphyton and Renalcis; diagenetic microfossils from calcification of coccoid blue-green algae. Journal of Sedimentary Petrology 54, 948–70.Google Scholar
Puckett, MK, McNeal, KS, Kirkland, BL, Corley, ME and Ezell, JE (2011) Biogeochemical stratification of carbonate dissolution precipitation in hypersaline microbial mats (Salt Pond, San Salvador, Tha Bahamas). Aquatic Geochemistry 17, 397418.CrossRefGoogle Scholar
Rees, MR, Pratt, BR and Rowell, AJ (1989) Early Cambrian reefs, reef complexes, and associated lithofacies of the Shackleton Limestone, Transantarctic Mountains. Sedimentology 36, 341–61.CrossRefGoogle Scholar
Reid, RP (1987) Nonskeletal peloidal precipitates in Upper Triassic reefs, Yukon Territory (Canada). Journal of Sedimentary Petrology 57, 893900.Google Scholar
Riding, R (2000) Microbial carbonate: the geological record of calcified bacterial-algal mats and biofilm. Sedimentology 47, 179214.CrossRefGoogle Scholar
Riding, R (2002) Structure and composition of organic reefs and carbonate mud mounds: concepts and categories. Earth-Science Reviews 58, 163231.CrossRefGoogle Scholar
Riding, R (2008) Abiogenic, microbial and hybrid authigenic carbonate crusts: components of Precambrian stromatolites. Geologia Croatica 61, 73103.CrossRefGoogle Scholar
Riding, R (2011) The nature of stromatolites: 3,500 million years of history and a century of research. In Advances in Stromatolite Geobiology (eds Reitner, J, Quéric, N-V and Arp, G), pp. 2974. Berlin: Springer-Verlag.CrossRefGoogle Scholar
Riding, R and Zhuravlev, AY (1995) Structure and diversity of oldest sponge–microbe reefs: Lower Cambrian, Aldan River, Siberia. Geology 23, 649–52.2.3.CO;2>CrossRefGoogle Scholar
Saadi, S, Hilali, E, Bensaïd, M, Boudda, A and Dahmani, M (1983) Carte Géologique de Maroc, Scale 1:1,000,000. Rabat: Ministère du l’Énergie et des Mines, Service Géologique du Maroc.Google Scholar
Sánchez-Román, M, Vasconcelos, C, Schmid, T, Dittrich, M, McKenzie, JA, Zenobi, R and Rivadeneyra, MA (2008) Aerobic microbial dolomite at the nanometer scale: implications for the geologic record. Geology 36, 879–82.CrossRefGoogle Scholar
Sass, H, Cypionka, H and Babenzien, H (2006) Vertical distribution of sulfate-reducing bacteria at the oxic-anoxic interface in sediments of oligotrophic Lake Stechlin. FEMS Microbiology Ecology 22, 245–55.CrossRefGoogle Scholar
Sass, AM, Eschemann, A, Kuhl, M, Thar, R, Sass, H and Cypionka, H (2002) Growth and chemosensory behavior of sulfate-reducing bacteria in oxygen–sulfide gradients. FEMS Microbiology Ecology 40, 4754.Google ScholarPubMed
Schmitt, M (1979) The Section of Tiout (Precambrian/Cambrian Boundary Beds, Anti-Atlas, Morocco): Stromatolites and their Biostratigraphy. Würzburg: Arbeiten aus dem Paläontologischen Institut Würzburg vol. 2, 188 pp.Google Scholar
Schmitt, M and Monninger, W (1977) Stromatolites and thrombolites in Precambrian/Cambrian boundary beds of the Anti-Atlas, Morocco: preliminary results. In Fossil Algae (ed. Flügel, E), pp. 80–5. Berlin: Springer.CrossRefGoogle Scholar
Shen, B, Qin, J, Tenger, B, Pan, A, Yang, Y and Bian, L (2017) Identification of bacterial fossils in marine source rocks in South China. Acta Geochimica 37, 6879.CrossRefGoogle Scholar
Spadafora, A, Perri, E, Mckenzie, J and Vasconcelos, C (2010) Microbial biomineralization processes forming modern Ca:Mg carbonate stromatolites. Sedimentology 57, 2740.CrossRefGoogle Scholar
Stephens, NP and Sumner, DY (2002) Renalcids as fossilized biofilm clusters. Palaios 17, 225–36.2.0.CO;2>CrossRefGoogle Scholar
Sun, SQ and Wright, VP (1989) Peloidal fabrics in Upper Jurassic reefal limestones, Weald Basin, southern England. Sedimentary Geology 65, 165–81.CrossRefGoogle Scholar
Tang, HS, Chen, YJ, Santosh, M, Zhong, H and Yang, T (2013) REE geochemistry of carbonates from the Guanmenshan Formation, Liaohe Group, NE Sino-Korean Craton: implications for seawater compositional change during the Great Oxidation Event. Precambrian Research 227, 316–36.CrossRefGoogle Scholar
Tang, DJ, Shi, XY, Jiang, GQ, Pei, Y and Zhang, W (2012) Mesoproterozoic biogenic thrombolites from the North China platform. International Journal of Earth Sciences 102, 401–13.CrossRefGoogle Scholar
Thomas, RJ, Fekkak, A, Ennih, N, Errami, E, Loughlin, SC, Gresse, PG, Chevallier, LP and Liégeois, JP (2004) A new lithostratigraphic framework for the Anti-Atlas Orogen, Morocco. Journal of African Earth Sciences 39, 217–26.CrossRefGoogle Scholar
Turner, EC, James, NP and Narbonne, GM (2000) Taphonomic control on microstructure in Early Neoproterozoic reefal stromatolites and thrombolites. Palaios 15, 87111.2.0.CO;2>CrossRefGoogle Scholar
Walsh, GJ, Benziane, F, Aleinikoff, JN, Harrison, RW, Yazidi, A, Burton, WC, Quick, JE and Saadane, A (2012) Neoproterozoic tectonic evolution of the Jebel Saghro and Bou Azzer-El Graara inliers, eastern and central Anti-Atlas Morocco. Precambrian Research 216, 2362.CrossRefGoogle Scholar
Walter, MR and Heys, GR (1985) Links between the rise of the metazoan and the decline of stromatolites. Precambrian Research 29, 149–74.CrossRefGoogle Scholar
Wilkin, R and Barnes, HL (1997) Formation processes of framboidal pyrite. Geochimica et Cosmochimica Acta 61, 323–39.CrossRefGoogle Scholar
Woo, J, Chough, SK and Han, Z (2008) Chambers of Epiphyton thalli in microbial buildups, Zhangxia Formation (Middle Cambrian), Shandong Province, China. Palaios 23, 5564.CrossRefGoogle Scholar
Zatoń, M, Kremer, B and Marynowskii, L (2012) Middle Jurassic (Bathonian) encrusted oncoids from the Polish Jura, southern Poland. Facies 58, 5777.CrossRefGoogle Scholar
Zhang, WH, Shi, X, Jiang, G, Tang, D and Wang, X (2015) Mass-occurrence of oncoids at the Cambrian Series 2–Series 3 transition: implications for microbial resurgence following an early Cambrian extinction. Gondwana Research 28, 432–50.CrossRefGoogle Scholar
Zhao, Y, Yan, H, Tucker, ME, Han, M, Zhao, H, Mao, G, Peng, C and Han, Z (2020) Calcimicrobes in Cambrian microbialites (Shandong, North China) and comparison with experimentally produced biomineralization precipitates. Carbonates and Evaporites 35, 115.CrossRefGoogle Scholar
Figure 0

Fig. 1. (a) Location map of the Anti-Atlas of Morocco. (b) Simplified geological sketch showing the distribution of the Precambrian–Cambrian outcrops in the Anti-Atlas Mountains (drawn after Saadi et al.1983). (c) Stratigraphic section through the lower Cambrian of the Fouanou syncline. (d) Detailed lithostratigraphic section of the studied horizon in the Fouanou syncline (the diameters of archaeocyath cups were measured within the levels L1 and L2).

Figure 1

Fig. 2. Macroscopic features of the thrombolite reef with archaeocyaths. (a) Outcrop photograph of thrombolite–archaeocyathan reefs characterized by successive reef-growth phases delimited by surfaces of reef-growth interruption (length of hammer scale is 29.5 cm). (b) Sample slab showing dark grey dendritic mesoclots and light grey matrix with scarce archaeocyaths (Arc). (c, d) Photographs and sketches of longitudinal section showing dendritic clotted fabric growing upwards (red arrows) (Arc – archaeocyath; Es – erosion surface). (e, f) Photographs of transverse sections showing small-sized regular and irregular archaeocyaths (Arc).

Figure 2

Fig. 3. Distribution patterns of the maximum diameter of 150 cups of archaeocyaths measured within two spaced levels (a) L1 and (b) L2 (shown in Fig. 1d). (c) Box-plots of cup diameters in both L1 and L2.

Figure 3

Fig. 4. Microscopic features of thrombolites observed under plane-polarized light. (a, b) Micrographs showing the various forms of Renalcis chambers (R) and Girvanella tubes. (c) Photomicrograph showing Epiphyton chambers (E) attached to archaeocyaths and surrounded by sparitic matrix (Sp). (d) A close-up view of the boxed area in (c) showing Epiphyton chambers with radiating filaments. (e) Photomicrograph of peloidal fabrics in the cryptic space between Renalcis chambers. (f) A close-up view of the boxed area in (e) showing the peloid (P) microspar fabric with a rare cloud of iron oxides (IO) derived from pyrite oxidation.

Figure 4

Fig. 5. Scanning electron microscopy photomicrographs and EDS of microbial structures in the micritic Renalcis chamber. (a) Close-up view of honeycomb-like structure consisting of translucent polygonal pits and walls interpreted as mineralized extracellular polymeric substance (EPS) matrix. (b) EDS spectrum and elemental quantitative data of the spot in (a). (c) EPS relics containing filamentous bacteria (Fb). (d) EDS spectrum and elemental quantitative data of the surface shown in (c) (Pt element resulted from platinum coating). (e, f) Elemental mappings of carbon (C) and calcium (Ca) of the surface in (c).

Figure 5

Fig. 6. Scanning electron microscopy photomicrographs of EPSs and bacterial fossils. (a) EPSs showing nano-sized cracks that possibly result from dehydration of EPS films during early diagenesis. (b) EPS relics coating micrite crystals with filamentous bacterial fossils. (c) Filamentous bacteria (Fb) grouped in a colony. (d) Magnified view of the boxed area in (c) showing the fine granular texture of the surface of bacteria with nano-sized cracks. (e) Grainy surface on possible organic residue. (f) Magnified view of the boxed area in (e) showing the micro-spherical form of possible coccoidal bacteria (CB) covering the surface of organic remains and associated mineralized EPSs.

Figure 6

Fig. 7. Scanning electron microscopy photomicrographs showing organominerals and detrital micrite in thrombolites. (a) Scattered nanoglobules (Ns) coalesced to form polyhedrons (Po) within EPS films. (b) Magnified view of the boxed area in (a) showing nanoglobules (Ns) and polyhedrons (Po) fused into micropeloids (Pe), closely associated with EPS relics. (c) Nanoglobules (Ns) coalesced to form polyhedrons (Po) and irregular micritic particles. (d) EDS spectrum and elemental quantitative data for nanoglobules (analysed spot (+) in (c)) (Pt element resulted from platinum coating). (e) Nanoglobules closely associated with EPSs and the probable filamentous bacteria (Fb). Nanoglobules (Ns) are visible on EPS flats. (f) Magnified view of the boxed area in (e) showing nanoglobules and nano-cracks resulting from dehydration of EPSs during early diagenesis.

Figure 7

Fig. 8. Scanning electron microscopy photomicrographs of pyrite framboids. (a, b) Abundant pyrite framboids (PF) consisting of equidimensional pyrite microcrystals associated with mucus-like EPS relics. (c) Close-up view of the boxed area in (b) showing pyrite framboid. (d) EDS spectrum of pyrite crystal in (c) (+ indicates the position of analysed spot). Fe, S and Ca elements are common in the pyrite crystals.

Figure 8

Fig. 9. Bulk rock mineralogical composition of selected samples from (a) the bottom and (b) the top of the lower reef complex of the Igoudine Formation (see Fig. 1d).

Figure 9

Fig. 10. (a, b) Schematic model showing thrombolite growth and (c, d) EPS mineralization process.