Abstract
Trace-fossil assemblages reflect the response of the benthos to sets of paleoenvironmental conditions during and immediately after sedimentation. Trace fossils have been widely studied in pelagic shelf and deep-sea chalk deposits from around the globe but never documented from ancient lagoonal chalk successions. Here we report the first detailed ichnologic analysis of a lagoonal chalk unit, using as an example the Upper Cretaceous Buda Formation from the Texas Gulf Coast Basin. In this unit, variable interconnection with the open ocean, accompanied by marked fluctuations in physicochemical parameters inherent to lagoonal circulation (e.g., salinity, hydrodynamic energy, bottom-water oxygenation), highly influenced the resultant trace-fossil content of the chalk. These lagoonal chalk deposits contain twenty ichnotaxa, displaying a clear dominance of Thalassinoides isp. and Chondrites isp., which are present in most of the bioturbated strata. The dominance of Thalassinoides isp., both in softgrounds as an element of the Cruziana Ichnofacies and in firmgrounds as a component of the Glossifungites Ichnofacies, highlights similarities with trace-fossil assemblages from shallow-water shelf-sea chalks. In contrast to both (open) shallow-water shelf-sea chalks and deep-sea chalks, the Buda Formation chalk exhibits more diverse assemblages and sharp fluctuations in ichnodiversity and ichnodisparity during relatively short periods of time. The increased ichnodiversity and ichnodisparity in this lagoonal chalk (in comparison with its open ocean counterparts) may reflect a complex interplay of taphonomic (i.e., incomplete bioturbation allowing preservation of shallow-tier trace fossils and ecologic (i.e., increased spatial environmental heterogeneity in the carbonate lagoonal setting) factors.
Introduction
Chalks have been differently defined in the literature1,2. The lithologic (diagenetic) definition considers chalk those firm, partly indurated oozes (calcareous nannofossils-rich sediments) that are friable1,3,4 and readily deformed by a fingernail or knife-blade1,3. The compositional definition, in contrast, characterizes chalks as carbonate deposits (of variable depositional texture, mudstone to packstone sensu Dunham5 classification6,7,8, when lithified), which are largely composed of calcareous nannofossils (mostly coccoliths) and micrite, with wide-ranging subordinate amounts of calcispheres, foraminifera, mollusks, echinoderms, and radiolarians, among other calcareous and siliceous components, irrespective of the induration2,6,7,8,9. Though most chalks have a dominant coccolith fraction, some chalks may exhibit dominant portions of micrite (or “micarbs”10) and planktonic foraminifera, with coccolith concentrations even below 20%11,12. For the purposes of this paper and acknowledging that (1) calcareous nannofossil-rich deposits undergo progressive lithification as a function of depth of burial and other factors, thus, any clear-cut distinction between soft, intermediate, and hard deposits is somewhat arbitrary9; and (2) the mixture of compositional and diagenetic terms in the lithological definition may lead to unnecessary complications and confusion2, the compositional definition of chalk is adopted.
Coccoliths are micron-sized calcitic plates secreted by unicellular phytoplankton, called coccolithophores13. Coccolithophores emerged during the Late Triassic and radiated during the Early Jurassic14. They originated in epeiric seas but during the Late Jurassic/Early Cretaceous migrated to deeper open-oceanic settings, where they became the dominant rock-forming carbonate particles until the present15,16. Nevertheless, under the warm/hot climate and high sea level that typified the Late Cretaceous17,18, massive chalk flourished in relatively shallow-water settings19,20, such as epeiric basins and continental shelves21, including marginal lagoonal environments22. This widespread chalk sedimentation was likely a response to a combination of factors, including (1) terrigenous sediment-starvation linked to high sea levels and/or arid climates23, (2) enlargement of areas of shelf sedimentation due to rising sea levels2,9, and (3) warm seawaters featuring low Mg/Ca ratios and high Ca concentrations that promoted coccolithophore production24,25.
Ichnology, the study of organism-substrate interactions, has proved to be highly successful in refining paleoenvironmental interpretations, although not all depositional environments have received the same degree of attention26,27. In particular, numerous ichnologic studies have focused on chalk19,20,21,28,29, and the ichnologic content of shelf-sea and deep-sea chalks has been compared19,30. However, no prior studies have been dedicated to the ichnology of chalks deposited under lagoonal conditions (i.e., in partially to almost fully enclosed shallow shelf settings).
The west-central Texas Buda Formation (commonly referred to as the Buda Limestone; Supplementary Fig. S1) comprises a lower Cenomanian chalk31,32,33 deposited on the broad Cretaceous Comanche Shelf of the Texas Gulf Coast Basin31,32,33,34. This chalk is characterized by a matrix which is visibly dominated by coccoliths debris, partly cemented coccoliths, and well-preserved coccoliths (see Supplementary Fig. S2). The calcite cement, where abundant, may substantially obscure the coccolith particles in this unit (Supplementary Fig. S2), which is a common phenomenon during the diagenetic evolution of some chalks35,36. The matrix of the Buda Formation can be classified either as “Microtexture 3” or as “Dispersed Clay Microtexture” sensu the “Pure” or “Impure” chalk microtexture classification of Saïag et al.8, depending on the CaCO3 content (higher or less than 96 wt.%, respectively). Valencia et al.32,33 reported an average CaCO3 content of 85 wt.% for the west-central Texas Buda Formation, with values ranging from 60 to 99 wt.%. As a comparison, lower Cenomanian chalk units from the Paris Basin has an average CaCO3 content of 75 wt.%, with values ranging from 52 to 95 wt.%8.
The Buda Formation was deposited under varying semi-restricted, slightly restricted to nearly open lagoonal conditions. The latter reflects a higher (but still partial) degree of connection with the open sea, largely controlled by the interplay of a wide and low-gradient paleotopography, together with topographic highs (e.g., Stuart City/Sligo paleo-reefal complex, Terrel Arch, San Marcos Arch) and fluctuating relative sea levels, under possible eustatic control32,33. Evidence includes (1) the thinning or pinching out of the Buda Formation in the Lower Cretaceous Stuart City/Sligo paleo-reefal complex37; (2) the broad and very low-gradient of the Buda Formation paleo-shelf38,39; (3) the endemic nature of the Buda Limestone ammonites (Budaiceras and Faraudiella40); (4) the occurrence of rapid salinity- and oxygen-fluctuating facies, e.g., the brackish-water Cribatina texana-bearing facies (WF1) rapidly transitioning to a normal-marine facies (WF232); (5) the highly-variable macrobenthos diversity and bioturbation intensity32,33,34; (6) the occurrence of a benthic fauna dominated by mollusks (largely oysters), echinoderms, calcispheres, and green-algae (dasycladales and bryopsidales)32,33,34; (7) a foraminiferal fraction dominated by benthonic species, with subordinated unkeeled planktonic communities, such as heterohelicids, favusellids and hedbergellids32,33; and (8) the occurrence of proximal tempestites32, low-angle cross-bedding and oolitic facies33; among other features32,33,34,39. This line of evidence not only testifies its lagoonal character and shallow-water nature but reflects a different extent of interconnection with the open ocean32,33.
The Buda Formation represents a unique opportunity to understand how ancient endobenthic communities responded to changing environmental parameters inherent to lagoonal circulation. Therefore, the aims of this study are to (1) document the trace-fossil content of the Buda Formation chalk, (2) compare the chalk ichnofauna of this unit with the trace-fossil content of chalk from shelf- and deep-sea settings, and (3) provide a characterization of lagoonal chalk trace-fossil assemblages that allows differentiating this more restricted setting from those present in chalk formed in the open sea. The underlying broad objective of this research is to expand the applications of ichnology to depositional environments that remain underexplored. Additionally, the outcome of this study illustrates the importance of integrating ichnologic and sedimentologic datasets in elucidating physicochemical parameters during deposition of ancient chalks in particular and carbonates in general.
Results
Sedimentologic characteristics
The west-central Texas Buda Formation consists of variably bioturbated chalky (coccolith-rich) mudstone to packstone that comprises nine main sedimentary facies (see Supplementary Table S1) interpreted to have been deposited in seven subenvironments, within a generalized lagoonal shelf setting32,33. These subenvironments, listed from lower to a higher grade of connection with the open sea, include (1) a shallow-subtidal, high-energy, brackish-water, semi-restricted lagoon; (2) a shallow-subtidal, low- to moderate-energy, oxygen-deficient (dysoxic), normal marine, semi-restricted lagoon; (3) a shallow-subtidal, moderate-energy, normal marine, slightly-restricted lagoon; (4) a shallow-subtidal, low-energy, normal marine, slightly-restricted lagoon; (5) a deep-subtidal, low-energy, normal marine, slightly-restricted lagoon, with episodic storm deposition; (6) a shallow-subtidal, moderate- to high-energy, normal marine, nearly open lagoon; and (7) a deep-subtidal, low energy, normal marine, nearly open lagoon32,33.
Trace-fossil content
Chalk facies in the Buda Formation contain a total of twenty ichnotaxa (Figs. 1, 2, 3, 4). These include seventeen bioturbation structures, namely Asterosoma isp. (Fig. 4b), Bergaueria isp. (Fig. 2h), Bichordites isp. (Fig. 2c), Chondrites isp. (Figs. 2b, d, 3c, 4b), ?Conichnus isp. (Fig. 3f), Gyrolithes isp. (Fig. 2i), Lockeia siliquaria (Fig. 2g), Palaeophycus isp. (Fig. 2e), Planolites isp. (Figs. 2e, 3c), Protovirgularia isp. (Fig. 2g), Rhizocorallium isp., Rosselia socialis, ?Sinusichnus isp. (Fig. 4e), Taenidium isp. (Fig. 2d), Teichichnus rectus (Fig. 2f), Thalassinoides isp. (Figs. 2a, i, 3a–g, 4c), and an unknown vertical trace fossil (Fig. 4c). In addition, three bioerosion structures, namely Gastrochaenolites isp. (Fig. 4d), Trypanites isp. (Fig. 2g) and indeterminate microborings (Fig. 4f), have been identified. Overall, the assemblage is dominated by Thalassinoides isp. and Chondrites isp., which are pervasive in most of the bioturbated deposits (Fig. 1, Supplementary Figs. S3–S5). In terms of subenvironments, the identified ichnotaxa are differentially distributed within the above-mentioned seven main lagoonal depositional settings, as detailed in the following sections.
Composite stratigraphic column of the Buda Formation in the Dryden-Comstock transect (west Texas), based on the DR1, DR16, DR17, DRD-B, and DR33-B outcrop sections, showing sedimentary facies, ichnotaxa and ichnofacies distribution, as well as their respective Bioturbation Index (BI) sensu Taylor and Goldring154 and percentual bioeroded area. Logs drawn by Fernando L. Valencia using Adobe Illustrator 2022 software version 26.2.
Dominant ichnotaxa identified in chalk from the Buda Formation: (a) basal view of Thalassinoides isp. [Th], A-1 locality; (b) cross-sectional view of an interval with pervasive Chondrites isp. [Ch], “Shanklin, W.R.2” core; (c) cross-sectional view of abundant Bichordites isp. (Bi) and its preservational variant “Laminites” [La], DR33-B locality; (d) cross-sectional view of polished slab showing Taenidium isp. cross-cut by ?Chondrites isp., DR1 locality; (e) cross-sectional view of Palaeophycus isp. [Pa] and Planolites isp. [Pl], “Shanklin, W.R.2” core; (f) cross-sectional view of Teichichnus rectus [Te], DR-33B locality; (g) basal view of deposits showing partially preserved Protovirgularia isp. [Pr] and adjacent Lockeia siliquaria [Lo] cross-cut by Trypanites isp. [Try], SA-1 locality; (h) cross-sectional view of Bergaueria isp. [Be], A-1 locality; (i) cross-sectional view of a passively filled (firmground) Thalassinoides isp., showing intergradation with Gyrolithes isp. [Gy] at the bottom, DR16 locality.
Representative photographs of trace fossils from the main lagoonal deposits: (a) and (b) show basal views of sparse Thalassinoides isp. [Th] in brackish-water lagoonal facies (WF1; BI = 2), DR16 locality; (c) cross-sectional core view showing the transition (base to top) from an oxygen-depleted subfacies (CF2b) to a more oxygenated deposit (CF2c) of a semi-restricted lagoonal setting; see the upward-increase in both bioturbation degree and the size of the deep-tier Chondrites isp. [Ch], “Shanklin, W.R.2” core; (d) cross-sectional view of highly bioturbated facies (WF2) in slightly restricted lagoonal subenvironment (BI = 4–5), DR16 locality; (e) basal view of moderately bioturbated deposits showing poorly preserved Thalassinoides isp. in a slightly restricted lagoonal facies (WF4b, BI = 4), DR33-B locality; (f) and (g) extremely bioturbated (BI = 6), nearly open lagoonal facies (CF4b) displaying by three-dimensional networks assigned to Thalassinoides isp., accompanied by minor ?Conichnus isp. [Co], A-1 locality.
Additional ichnotaxa from the Buda Formation: (a) cross-sectional view of Rosselia isp. [Ro] in WF4c, DR1 locality; (b) cross-sectional view of proximal tempestites (WF5) showing Asterosoma isp. [As] cross-cut by deeper-tier Chondrites isp. [Ch], DR16 locality; (c) cross-sectional view of a proximal tempestite (WF5) showing an unknown vertical trace [Uv] near the base of the erosive deposit (WF5a), followed upwards by a hummocky-cross-bedded and more bioturbated sub-facies at the topmost (preserved) tempestite (WF5d); see Thalassinoides isp. [Th] cross-cut by Chondrites isp. [Ch] at this upper interval, DR16 locality; (d) cross-sectional view of locally abundant Gastrochaenolites isp. [Ga] in WF1, DR16 locality; (e) top view of a passively-filled (firmground) ?Sinusichnus isp. in WF2, DR16 locality; (f) SEM picture of clay-filled microboring [Mi] cross-cutting the recrystallized chalk matrix and a calcite-cemented bioclast.
Softground trace-fossil assemblages in semi-restricted lagoonal settings (Figs. 1, 2a,b,e, 3a–c, 4d and Supplementary Figs. S3–S5)
The semi-restricted lagoonal subenvironment is represented by brackish-water packstone (WF1) and oxygen-deficient (dysoxic) mudstone to packstone (CF1a-b and CF2a-c)32,33. In general, these facies are the least bioturbated and show the softground trace-fossil assemblages with the lowest ichnodiversity (richness in ichnotaxa41,42) and ichnodisparity (variability of morphological plans in the biogenic structures41,42) of the studied strata. The oyster-rich packstone (WF1), representative of the brackish-water lagoonal setting, is characterized by low to moderate bioturbation degree (BI = 2–3), comprising monospecific suites of decapod burrows43,44 represented by Thalassinoides isp., which is interpreted as a mid-tier burrow cross-cut by a subsequent and deeper-tier generation of Thalassinoides isp. (Fig. 3a,b). Likewise, the calcisphere-rich wackestone–packstone (CF1a–b) and wispy-laminated mudstone–wackestone (CF2a–c), characteristic of the dysoxic lagoonal setting, display impoverished but slightly more diverse suites, with highly variable bioturbation intensity (BI = 1–4). Sparse burrowing activity (BI = 1–2) is recorded in the pyrite- and glauconite-richer subfacies (CF2b) linked to the more oxygen-depleted periods33 (Fig. 3c). The trace-fossil suites occurring in these deposits are largely composed of deep-tier Chondrites isp. of variable sizes (Figs. 2b, 3c), made by either lucinid bivalves or vermiform animals45, which are cross-cutting mid-tier common to rare Thalassinoides isp. and subordinated occurrences of shallow-tier worm-like trace fossils46 assigned to Planolites isp. (Figs. 2e, 3c) and Palaeophycus isp. (Fig. 2e). In addition, rare Rhizocorallium isp., likely produced by crustaceans47, is present locally.
Softground trace-fossil assemblages in slightly restricted lagoonal settings (Figs. 1, 3d,e, 4b,c)
The slightly restricted lagoonal setting comprises both the clay-/quartz-richer mudstone to wackestone facies from the low-energy, shallow- to deep-subtidal setting (WF3, WF4b) and the coccolith-richer wackestone to packstone from the more energetic shallow-subtidal subenvironment (WF2)32,33. These deposits are characterized by a more intense bioturbation degree and by trace-fossil suites with an increase in ichnodiversity in comparison with the more enclosed subenvironments (semi-restricted lagoon). The trace-fossil content in slightly restricted settings is largely limited to Thalassinoides isp. (Fig. 3d,e), Chondrites isp., Planolites isp., Palaeophycus isp., Taenidium isp. (typically attributed to worm-like animals48), and Bichordites isp. (including its preservational variant49,50 “Laminites”, attributed to sea urchins51). The bioturbation intensity varies from BI = 2–4, with the lower burrowing activity recorded in the terrigenous sediment-richer facies. Proximal tempestites (WF5a–d) formed in the deep-subtidal, slightly restricted lagoonal subenvironment show reduced bioturbation intensity (BI = 1–3) and ichnodiversity when compared with the background sedimentary facies (WF4b). These event beds are also characterized by the presence of worm-like trace fossils52,53 assigned to Asterosoma isp. (Fig. 4b) and Teichichnus rectus, as well as by Bichordites isp. and an unknown vertical trace fossil (Fig. 4c).
Softground trace-fossil assemblages in nearly open lagoonal settings (Figs. 1, 2d–f, 2h,i, 3f,g and Supplementary Figs. S3–S5)
The nearly open lagoonal deposits comprise the shallow-subtidal, moderate- to high-energy, wackestone to packstone facies of central Texas (CF3, CF4a–c), and the deep-subtidal, low-energy, mudstone to wackestone from western Texas (WF4a, WF4c). These more ocean-flushed chalk deposits of the Buda Formation are characterized by the highest bioturbation degree, as well as by the highest ichnodiversity and ichnodisparity in the softground trace-fossil suites. Stenohaline fauna-rich wackestone–packstone facies, representative of the shallow-subtidal, moderate- to high-energy, nearly open marine lagoonal setting (CF3, CF4a–c), are characterized by pervasive bioturbation (BI = 4–6), high ichnodiversity, and high ichnodisparity. Burrows include pervasive three-dimensional boxwork-like networks assigned to mid-tier Thalassinoides isp. (Fig. 3f,g), intergrading with rare spiral vertical burrows (Gyrolithes isp.), cross-cutting shallow-tier Planolites isp., and rare bivalve trace fossils54 attributed to Lockeia siliquaria and Protovirgularia isp. (Fig. 2g). These networks are overprinted by rare mid-tier burrowing anemone structures55 included in Bergaueria isp. (Fig. 2h) and ?Conichnus isp. (Fig. 3f), or more commonly by abundant deep-tier Chondrites isp. Mudstone and skeletal wackestone, from similar nearly open marine lagoonal but deeper-subtidal and quieter-water settings (WF4a, WF4c), are also characterized by pervasive bioturbation (BI = 4–6) with increased ichnodiversity and ichnodisparity. These assemblages are typically composed of shallow-tier Planolites isp. and Palaeophycus isp., cross-cut by mid-tier Thalassinoides isp., which in turn, is overprinted by deeper mid-tier Taenidium isp. (Fig. 2d), as well as by subordinated Bichordites isp. and its preservational variant “Laminites” (Fig. 2c). Accessory mid-tier burrows include worm trace fossils52,53,56 assigned to Teichichnus rectus (Fig. 2f), Asterosoma isp., and Rosselia socialis (Fig. 4a). All these shallow- to mid-tier ichnotaxa are cross-cut by deep-tier ?Chondrites isp. (Fig. 2d).
Firmground and hardground trace-fossil assemblages (Figs. 1, 2g,i, 4d–f and Supplementary Figs. S3–S5)
In addition to the softground ichnotaxa, overprinting firmground and hardground trace-fossil suites occur in the Buda Formation. Firmground trace fossils are abundant and distributed in the different depositional subenvironments, as well as within major (e.g., sequence boundary, maximum flooding surface) and minor (e.g., flooding surface) stratigraphic surfaces. Firmground trace fossils include Thalassinoides isp. with rare Gyrolithes isp. terminations (Fig. 2i), and ?Sinusichnus isp. (Fig. 4e). The hardground trace fossils, on the other hand, consist of bivalve borings57 assigned to Gastrochaenolites isp. (Fig. 4d), the worm-produced boring58 Trypanites isp. (Fig. 2g), and an indeterminate microboring only visible under back-scattered electron microscopy analysis (Fig. 4f). These bioeroding structures are usually sparse (yet locally covering up to 40% of the rock fabric) and largely linked to major stratigraphic surfaces, such as sequence boundaries and maximum flooding surfaces. As in the case of the firmground burrows, the bioerosion trace fossils are not linked to a specific lagoonal subenvironment but are more commonly distributed through all the shallower-water chalk deposits from central Texas.
Discussion
Lagoons are shallow-neritic water bodies developed on platforms that are generally protected by wide shallow seas, by reef trends, by sand-shoal barriers, or by islands59,60. Several studies in lagoons and nearshore settings have shown that physicochemical stress factors, such as freshwater discharge, hydrodynamic energy, sedimentation rate, water turbidity, and bottom-water oxygenation, have a considerable impact on the benthos, therefore influencing trace-fossil composition61,62,63. Substantial freshwater discharge and the resultant brackish-water conditions have been widely acknowledged as major stressors in marginal-marine systems61,64,65. In the Buda Formation, the brackish-water chalk interval is characterized by a depauperate Cruziana Ichnofacies (Fig. 1), with extremely low ichnodiversity and ichnodisparity (monospecific suite of Thalassinoides isp.), and low to moderate bioturbation (BI = 2–3), in agreement with the basic tenets of the brackish-water trace-fossil model64,65. In fact, ichnodisparity and ichnodiversity increase parallel to an increase in the degree of connection with the open sea.
Overall, the characteristics of the Buda Formation trace-fossil assemblages indicate that endobenthic colonization of this chalk occurred during low-energy periods, as indicated by the generalized scarcity of vertical dwelling burrows and escape trace fossils, the abundance of horizontally oriented endobenthic structures, and the overall high bioturbation intensity66,67. Nevertheless, this was not the case for the proximal tempestites facies. Therein, (1) the dominant vertical components of the Thalassinoides isp. networks, (2) the occurrence of unknown vertical trace fossils, and (3) the relatively low bioturbation intensity of these event layers (BI = 1–3) compared to the slowly settled background deposits (BI = 2–5), likely reflect that, despite most endobenthic colonization occurred during a waning stage of the flow, energy was persistently high near the bed67. The rate of sediment accumulation is considered to have a major impact on the colonization window and the consequent bioturbation intensity29. Rapid sedimentation frequently reduces or inhibits bioturbation68, as in the case of the tempestites, whereas slow rates of sedimentation represent the ideal scenario for intense burrowing activity69. In stratigraphic sequences, sediment accumulation rates are controlled by the interplay between sediment supply and accommodation70. Unlike in siliciclastic sediments, sediment supply in carbonate systems may not only be controlled by changes in physical energy (e.g., storms, turbidity currents) but by the productivity of the carbonate factory71. In the Buda Formation, the carbonate factory was largely controlled by changing climate conditions, sea level, and variable water turbidity32. The more productive times (i.e., periods with increased sedimentation rate) were characterized by high sea levels, higher temperatures, and quieter and less turbid waters32. Interestingly, however, the most bioturbated facies are those associated with the most carbonate productive and less clay-diluted cycles (Lechuguilla and Love Station members32) (i.e., cycles characterized by increased sedimentation, thus somehow contradicting the influence of sedimentation rate on the colonization window). Nevertheless, the relatively reduced bioturbation intensity in the slowly settled and clay-richer depositional cycle (Red Light Member32) may not have been a response to changes in sedimentation rates but a consequence of other significant coeval operating stress factors, such as elevated water turbidity, which is known as an important stress factor for the benthic communities72.
Oxygen content has been widely regarded as a major environmental stress factor on the benthos29,73. From an ichnologic perspective, progressive dysoxia is generally reflected by decreasing (1) ichnodiversity, (2) bioturbation intensity, (3) burrow size, and (4) burrow penetration74. These organism responses, however, may have been induced by several other physicochemical parameters (e.g., substrate consistency) or taphonomic factors, rather than decreasing oxygenation levels75. In the Buda Formation, dominantly oxic bottom-water conditions are expressed by the overall abundant bioturbation intensity and ichnodiversity. Nevertheless, facies with reduced bioturbation intensity and ichnodiversity, and concomitant occurrences of (locally) abundant pyrite and small-sized Chondrites (e.g., CF2b; Fig. 3c), might reflect an endobenthic response to times of oxygen-depleted (dysoxic) bottom-waters73,76.
Some of the above-mentioned factors (e.g., dysoxia) may also operate in open shelf- and deep-sea environments. Hence, it is not surprising that shelf-sea chalks (epicratonic) and deep-sea chalks (bathyal–abyssal)19,30 show some similarities in ichnofaunal content with the Buda Formation21,28,29,30,77,78,79,80,81,82,83,84,85,86,87,88,89,90,91,92,93,94,95,96,97,98,99,100,101,102,103,104,105,106,107,108,109,110,111,112,113,114,115,116,117,118,119,120,121,122,123,124,125,126,127,128,129,130,131,132,133,134,135,136,137,138,139,140,141,142,143 (Table 1; Supplementary Table S2). Shelf- and deep-sea chalks are composed of trace-fossil suites largely attributable to the Seilacherian Zoophycos Ichnofacies, with abundant occurrences of Chondrites, Zoophycos, and Planolites, as well as common Teichichnus (Fig. 5a,b; Table 1, Supplementary Table S2). However, the deep-sea chalk deposits differ from their shelf counterparts by the lower occurrences of decapod burrows, such as Ophiomorpha and Thalassinoides; the latter being the dominant ichnogenus in shelf-sea settings (Fig. 5a,b; Table 1; Supplementary Table S2). Moreover, among the recurring chalk ichnogenera, Palaeophycus, Phycosiphon, Taenidium, and Trichichnus are consistently absent or rare in deep-sea chalk deposits (Fig. 5a,b; Table 1; Supplementary Table S2). Skolithos, on the other hand, seems to be more common in deep-sea chalks (Fig. 5a,b). Shelf-sea chalks also show some differences between their bathymetrical end-members (Supplementary Table S2). For example, chalks accumulated in shallow-water environments (e.g., inner shelf) contain trace-fossil suites dominated by Thalassinoides with very rare or absent Zoophycos, attributable to the Cruziana Ichnofacies. Deeper-water shelf-sea chalks (e.g., outer shelf, distal epeiric basins), in contrast, exhibit trace-fossil suites with abundant occurrences of Zoophycos that illustrate the Zoophycos Ichnofacies. Taking into consideration the abundance of Thalassinoides in both shallow- and deep-shelf settings (Supplementary Table S2), the scarcity/absence of Zoophycos seems to be critical in discriminating between these two environments on ichnologic grounds.
Distribution of the most recurring chalk ichnotaxa in shelf-sea (a) versus deep-sea (b) environments. Ch = Chondrites; Cy = Cylindrichnus; Gy = Gyrolithes; Op = Ophiomorpha; Pa = Palaeophycus; Ph = Phycosiphon; Pl = Planolites; Sk = Skolithos; Ta = Taenidium; Te = Teichichnus; Th = Thalassinoides; Tr = Trichichnus; Zo = Zoophycos.
In general, and somewhat unsurprising given their close bathymetric proximity, the trace-fossil assemblages of the Buda Formation are like those of the shallow-water shelf-sea chalks (Table 1, Supplementary Table S2), as indicated by trace-fossil suites dominated by the ichnogenera Thalassinoides and Chondrites, and lacking Zoophycos, therefore illustrating the Cruziana Ichnofacies. Likewise, the common occurrences of the substrate-controlled Glossifungites and Trypanites ichnofacies reflect similarities with ichnofaunas recorded in shallow-water shelf-sea chalks. Nevertheless, the lagoonal Buda Formation chalk shows ichnologic features that differ from those of (open) shallow-water shelf-sea deposits, which may be attributable specifically to its lagoonal character. These features include (1) overall higher ichnodiversity and ichnodisparity levels in lagoon deposits, and (2) abrupt vertical changes in trace-fossil content, reflecting different expressions of the Cruziana Ichnofacies. These differences in trace-fossil content between chalk formed under open marine conditions and chalk formed in a lagoonal setting reflect a complex interplay of ecologic and taphonomic factors.
In comparison with chalk formed under open marine conditions, the studied lagoon chalk trace-fossil assemblages typically show higher ichnodiversity and ichnodisparity. Average ichnodiversity and ichnodisparity in shelf chalks are 9 and 7, respectively (n = 24; Supplementary Table S2). Of all these units, the highest ichnodiversity and ichnodisparity have been recorded in the Upper Cretaceous Austin Chalk (19 bioturbation ichnotaxa and 14 categories of architectural design), which is the only one showing similar ichnodiversity and ichnodisparity levels to those of the Buda Formation (20 ichnospecies and 17 categories of architectural design, respectively). In addition, the Buda Formation contains the bivalve trace fossils Lockeia siliquaria and Protovirgularia isp., and the burrowing anemone trace fossils Bergaueria isp. and ?Conichnus isp., all previously unrecorded in chalk anywhere. Though the Buda Formation deposits are dominantly normal marine in character (except by the brackish-water WF1), the fact that ichnodiversity and ichnodisparity levels are higher in lagoonal settings than in the open sea seems to be inconsistent with current ideas regarding ichnology of marginal-marine environments. However, this apparent anomaly can be explained by invoking an interplay of taphonomic and ecologic controls. Ichnodiversity in shelf and deep-sea chalk is typically relatively low. However, this low level may reflect taphonomic overprint due to the extremely high bioturbation degree in these deposits108, resulting in ichnofabrics of low fidelity showing a preservational bias towards elite trace fossils144. Intense bioturbation may have allowed preferential preservation of deep-tier trace fossils, preventing preservation of those emplaced in shallow tiers, therefore artificially decreasing ichnodiversity145. In other words, intense bioturbation is masking the true diversity levels of animal activity in these open marine settings. Although the degree of bioturbation in the studied lagoonal chalk is overall relatively high, not all intervals have suffered biogenic reworking to the same extent that those formed under fully marine conditions. This allowed keeping open a taphonomic window that promoted the preservation of shallow-tier trace fossils, therefore contributing to a diversity increase that reflects enhanced ichnologic fidelity.
In addition to this taphonomic overprint, spatial heterogeneity may have played a role in promoting overall high ichnodiversity and ichnodisparity levels in the lagoonal Buda Formation. Increased environmental heterogeneity along a broad spectrum of spatial scales is known to enhance diversity146,147. Specifically, carbonate lagoons may have been host to a complex mosaic of habitats contributing to both within- and between-community variability148. A comprehensive study dealing with geographic patterns of marine benthos biodiversity along the European coasts showed that lagoons tend to be considerably higher in species density and diversity than open coast systems149. Furthermore, the relatively high depositional depth variance within the Buda Formation, which include very-shallow subtidal to deep subtidal lagoonal settings (above SWB)32,33, maybe also responsible for increased diversity in this unit150.
The sharp changes in trace-fossil content in the Buda Formation chalk are evidenced, for example, by the abrupt vertical replacement of the depauperate, monospecific suite of the Cruziana Ichnofacies occurring in the brackish-water deposits (WF1) by the more diverse expression of this ichnofacies that characterizes the overlying more marine and pervasively bioturbated deposits formed in less restricted lagoonal settings (WF2; Fig. 1), therefore most likely reflecting a lower incidence of the salinity stressor. Another example is noted with the sharp switch from deposits (CF2c) having the impoverished proximal Cruziana Ichnofacies to the overlying highly bioturbated deposits (CF4b) containing the archetypal Cruziana Ichnofacies (Supplementary Figs. S3–S5), due to a substantial upward increase in bottom-water oxygenation. This vertical variability in the different expressions of the Cruziana Ichnofacies in the Buda Formation may represent another distinguishing feature of lagoonal chalks, as a reflection of the rapidly fluctuating physicochemical conditions in this marginal marine setting151.
Conclusions
The ichnologic content of the lagoonal chalk deposits from the Buda Formation is similar to those of the (open) shallow-water shelf-sea chalks, as represented by ubiquitous Thalassinoides isp. and Chondrites isp., together with the absence or scarcity of Zoophycos isp. Nevertheless, the studied lagoonal chalk displays higher both ichnodiversity and ichnodisparity than its open ocean counterpart. This relatively richer endobenthic community in the Buda Formation chalk may be the result of increased environmental variability in the lagoonal realm and the effect of differential taphonomic processes in comparison to the open ocean chalks.
Methods
Material
This ichnologic study is based on Buda Formation sections previously assessed in sedimentologic and stratigraphic studies by Valencia et al.32,33 in the west-central Texas region. It comprises the analysis of seven outcrops (A-1, SA-1, DR1, 16, DR17, DRD-B, DR33-B), and one cored-section (“Shanklin, W.R. 2”), where nine main sedimentary facies were described32,33 (see Supplementary Table S1 and Supplementary Fig. S1 for facies summary and outcrops/well-core locations, respectively). A total of ten rock slabs representative of most sedimentary facies were collected and polished at the facilities of the University of Saskatchewan. Material lacking a good trace fossil-host rock color contrast was photographed and digitally treated using Adobe Photoshop software (version 21.2.3) to enhance trace-fossil recognition, by using techniques developed by Dorador and Rodriguez-Tovar152,153, where adjustments of image levels, contrast/brightness, and vibrance were implemented. In addition, selected rock samples were prepared for back-scattered electron microscopy analysis (SEM), using the Phenom-World Phenom XL scanning electron microscope at the Texas A&M University at College Station.
Ichnologic analysis
The ichnologic characterization of the studied material (outcrops, cores, and polished rock-slabs) included ichnotaxonomic descriptions, tiering analysis, and semi-quantitative estimation of the bioturbation intensity via the Bioturbation Index (BI) of Taylor and Goldring154. This index is a widely applied bioturbation intensity scheme that comprises seven categories. BI = 0 indicates no bioturbation (0%). BI = 1 is represented by sparse bioturbation (1–4%) with few discrete trace fossils. BI = 2 represents low bioturbation (5–30%). BI = 3 indicates moderate bioturbation (30–61%), with rare overlapping of the traces. BI = 4 indicates high bioturbation (61–90%), with common overlapping of the traces. BI = 5 typified sediment with intense bioturbation (91–99%), with abundant overlapping a limited reworking. BI = 6 illustrates fully bioturbated (100%) and totally reworked sediment, due to repeated overprinting of the biogenic structures. For the degree of bioerosion, a percentage of area occupied by borings was quantitatively assessed in photographed material, using a combination of the Adobe Photoshop and ImageJ software for boring-area calculations following the method in Cao et al.155. This method includes (1) delineation of the boring/bioeroded area using Adobe Photoshop’s “lasso tool” and painting it in black; followed by the (2) measurements of the “total area” and “bioeroded area” (in pixels) using the “wand (tracing) tool” in ImageJ; and (3) the final calculation of the bioerosion percentage in the studied image. SEM observations, on the other hand, were limited to the identification of biogenic structures non-visible under macroscopic analysis. In addition, we have compiled a comprehensive global dataset of trace fossils in chalk based on literature evaluation (Supplementary Table S2). Each of the recorded trace-fossil occurrences has been checked and the ichnotaxonomy revised to use a consistent classification framework.
Data availability
All data generated or analysed during this study are included in this published article [and its supplementary information files].
References
Bromley, R. G. & Gale, A. S. The lithostratigraphy of the English Chalk Rock. Cretac. Res. 3, 273–306 (1982).
Scholle, P. A., Arthur, M. A. & Ekdale, A. A. Pelagic environment. In Carbonate Depositional Environments (eds Scholle, P. A. et al.) 619–691 (Am. Ass. Petrol. Geol. Mem. 33, 1983).
Gealy, E. L., Winterer, E. L. & Moberly, R. Methods, conventions, and general observations. Initial Rep. Deep Sea Drill. Proj. 7, 9–26 (1971).
Kroenke, L. W. et al. Ocean Drilling Program. Proc. ODP, Init. Repts. 130, College Station (1991).
Dunham, R. L. Classification of carbonate rocks according to depositional texture. Mem. Am. Assoc. Petrol. Geol. 1, 108–121 (1962).
Quine, M. & Bosence, D. Stratal geometries, facies and sea-floor erosion in Upper Cretaceous chalk, Normandy, France. Sedimentology 38, 1113–1152 (1991).
Røgen, B., Gommesen, L. & Fabricius, I. L. Grain size distributions of Chalk from Image analysis of electron micrographs. Comput. Geosci. 27, 1071–1080 (2001).
Saïag, J. et al. Classifying chalk microtextures: Sedimentary versus diagenetic origin (Cenomanian–Santonian, Paris Basin, France). Sedimentology 66, 2976–3007 (2019).
Scholle, P. A. Chalk diagenesis and its relation to petroleum exploration: Oil from chalks, a modern miracle?. Bull. Am. Assoc. Petrol. Geol. 61, 982–1009 (1977).
Tagliavento, M., John, C. M., Anderskouv, K. & Stemmerik, L. Towards a new understanding of the genesis of chalk: Diagenetic origin of micarbs confirmed by clumped isotope analysis. Sedimentology 68, 513–530 (2021).
Bramlette, M. N. Significance of coccolithophorids in calcium-carbonate deposition. Bull. Geol. Soc. Am. 69, 121–126 (1958).
Hattin, D. E. & Darko, D. A. Technique for determining coccolith abundance in shaly chalk of Greenhorn Limestone (Upper Cretaceous) of Kansas. Kansas Geol. Surv. Bull. 202, 1–11 (1971).
Houghton, S. D. Calcareous nannofossils. In Calcareous algae and Stromatolites (ed. Riding, R.) 217–266 (Springer, 1991).
Bown, P. R., Lees, J. A. & Young, J. R. Calcareous nannoplankton evolution and diversity through time. In Coccolithophores—From Molecular Processes to Global Impact (eds Thierstein, H. R. & Young, J. R.) 481–508 (Springer, 2004).
Roth, P. H. Mesozoic paleoceanography of the North Atlantic and Tethys Oceans. In North Atlantic Paleoceanography (eds Summerhayes, C. P. & Shackleton, N. J.) 299–320 (Geological Society Special Publications, 1986).
Baumann, K.-H., Andruleit, H., Böckel, B., Geisen, M. & Kinkel, H. The significance of extant coccolithophores as indicators of ocean water masses, surface water temperature, and paleoproductivity: A review. Paläontol. Z. 79, 93–112 (2005).
Miller, K. G. et al. The phanerozoic record of global sea-level change. Science 310, 1293–1298 (2005).
Ando, A., Huber, B. T., MacLeod, K. G. & Watkins, D. K. Early Cenomanian “hot greenhouse” revealed by oxygen isotope record of exceptionally well-preserved foraminifera from Tanzania. Paleoceanography 30, 1556–1572 (2015).
Ekdale, A. A. & Bromley, R. G. Comparative ichnology of shelf-sea and deep-sea chalk. J. Paleontol. 58, 322–332 (1984).
Savrda, C. E. Chalk and related deep-marine carbonates. In Trace Fossils as Indicators of Sedimentary Environments (eds Knaust, D. & Bromley, R. G.) 777–806 (Elsevier, 2012).
Savrda, C. E., Foster, C. & Fluegeman, R. A unique Lower Paleocene shelf-sea chalk in the eastern U.S. Gulf coastal plain (Clayton Formation, western Alabama): Implications for depositional environment, sea-level dynamics and paleogeography. Palaeogeogr. Palaeoclimatol. Palaeoecol. 538, 109439 (2020).
Erba, E., Watkins, D. & Mutterlose, J. Campanian dwarf calcareous nannofossils from Wodejebato Guyot. In Proc. Ocean Drill. Program Sci. Results (eds Haggerty, J. A. et al.) 141–155 (Ocean Drilling Program, 1995).
Hancock, J. M. The petrology of chalk. Proc. Geol. Assoc. 86, 499–535 (1975).
Stanley, S. M. & Hardie, L. A. Secular oscillations in the carbonate mineralogy of reef-building and sediment-producing organisms driven by tectonically forced shifts in seawater chemistry. Palaeogeogr. Palaeoclimatol. Palaeoecol. 144, 3–19 (1998).
Stanley, S. M., Ries, J. B. & Hardie, L. A. Seawater chemistry, coccolithophore population growth, and the origin of Cretaceous chalk. Geology 33, 593–596 (2005).
Pemberton, S. G. et al. Ichnology and sedimentology of shallow to marginal marine systems: Ben Nevis and Avalon Reservoirs, Jeanne d’Arc Basin. Geol. Assoc. Can. Short Course Notes 15, 1–343 (2001).
Buatois, L. A. & Mángano, M. G. Ichnology: Organism–Substrate Interactions in Space and Time (Cambridge Press University, 2011).
Frey, R. W. & Bromley, R. G. Ichnology of American chalks: The Selma Group (Upper Cretaceous), western Alabama. Can. J. Earth Sci. 22, 801–828 (1985).
Savrda, C. E. & Bottjer, D. Trace-fossil model for reconstructing oxygenation histories of ancient marine bottom waters: Application to Upper Cretaceous Niobrara Formation, Colorado. Palaeogeogr. Palaeoclimatol. Palaeoecol. 74, 49–74 (1989).
Kennedy, W. J. Trace fossils in carbonate rocks. In The Study of Trace Fossils (ed. Frey, R. W.) 377–398 (Springer, 1975).
Loucks, R. G., Gates, B. G. & Zahm, C. K. Depositional systems, lithofacies, nanopore to micropore matrix network, and reservoir quality of the Upper Cretaceous (Cenomanian) Buda Limestone in Dimmit County, southwestern Texas. Gulf Coast Assoc. Geol. Soc. 8, 281–300 (2019).
Valencia, F. L. et al. Depositional environments and controls on the stratigraphic architecture of the Cenomanian Buda Limestone in west Texas, U.S.A. Mar. Petrol. Geol. 133, 105275 (2021).
Valencia, F. L., Laya, J. C., Buatois, L. A., Mángano, M. G. & Valencia, G. L. Sedimentology and stratigraphy of the Cenomanian Buda Limestone in central Texas, U.S.A.: Implications on regional and global depositional controls. Cretac. Res. 137, 105231 (2022).
Martin, K. G. Stratigraphy of the Buda Limestone, south-central Texas. In Comanchean (Lower Cretaceous) Stratigraphy and Paleontology of Texas (ed. Hendricks, L.) 287–299 (Permian Basin Section SEPM 67 (8), 1967).
Mallon, A. J. & Swarbrick, R. E. Diagenetic characteristics of low permeability, non-reservoir chalks from the Central North Sea. Mar. Petrol. Geol. 25, 1097–1108 (2008).
Brasher, J. E. & Vagle, K. R. Influence of lithofacies and diagenesis on Norwegian North Sea chalk reservoirs. Am. Assoc. Petrol. Geol. Bull. 80, 746–769 (1996).
Hentz, T. F. & Ruppel, S. C. Regional stratigraphic and rock characteristics of eagle ford shale in its play area: Maverick Basin to East Texas Basin. Am. Ass. Petrol. Geol. Search and Discovery 10325 (2011).
Robinson, W. C. Petrography and depositional environments of the Buda Limestone, northern Coahuila, Mexico. MS Thesis. The University of Texas, 156 (1982).
Reaser, D. F. & Robinson, W. C. Cretaceous Buda Limestone in west Texas and northern Mexico. In Cretaceous Stratigraphy and Paleoecology, Texas and Mexico (ed. Scott, R. W.) 337–373 (Perkins Memorial volume, GCSSEPM Foundation, Special Publications in Geology 1, 2003).
Young, K. P. Cretaceous paleogeography: Implications of endemic ammonite faunas. Geol. Circ. (University of Texas at Austin, Bureau of Economic Geology) 72, 1–13 (1972).
Buatois, L. A. & Mángano, M. G. Ichnodiversity and ichnodisparity: Significance and caveats. Lethaia 46, 281–292 (2013).
Buatois, L. A., Wisshak, M., Wilson, M. A. & Mángano, M. G. Categories of architectural designs in trace fossils: A measure of ichnodisparity. Earth Sci. Rev. 164, 102–181 (2017).
Swinbanks, D. D. & Luternauer, J. L. Burrow distribution of thalassinidean shrimp on a Fraser Delta tidal flat, British Columbia. J. Paleontol. 61, 315–333 (1987).
Carmona, N. B., Buatois, L. A. & Mángano, M. G. The trace fossil record of burrowing decapod crustaceans: Evaluating evolutionary radiations and behavioural convergence. In Trace Fossils in Evolutionary Palaeoecology (eds Webby, B. D. et al.) 141–153 (Wiley, 2004).
Baucon, A. et al. Ethology of the trace fossil Chondrites: Form, function and environment. Earth Sci. Rev. 202, 102989 (2020).
Pemberton, S. G. & Frey, R. W. Trace fossil nomenclature and the Planolites–Palaeophycus dilemma. J. Paleontol. 56, 843–881 (1982).
Rodríguez-Tovar, F. J. & Pérez-Valera, F. Trace fossil Rhizocorallium from the Middle Triassic of the Betic Cordillera, Southern Spain: Characterization and environmental implications. Palaios 23, 78–86 (2008).
Bown, T. M. & Kraus, M. J. Ichnofossils of the alluvial Willwood Formation (lower Eocene), Bighorn Basin, northwest Wyoming, USA. Palaeogeogr. Palaeoclimatol. Palaeoecol 43, 95–128 (1983).
Uchman, A. Taxonomy and palaeoecology of flysch trace fossils: The Marnoso-arenacea Formation and associated facies (Miocene, Northern Apennines, Italy). Beringeria 15, 3–115 (1995).
Demírcan, H. & Uchman, A. The miniature trace fossil Bichordites kuzunensis isp. Nov., from early Oligocene prodelta sediments of the Mezardere Formation, Gökçeada Island, NW Turkey. Acta Geol. Pol. 62, 205–215 (2012).
Plaziat, J.-C. & Mahmoudi, M. Trace fossils attributed to burrowing echinoids: A revision including new ichnogenus and ichnospecies. Geobios 21, 209–233 (1988).
Chamberlain, C. K. Morphology and ethology of trace fossils from the Ouachita Mountains, southeast Oklahoma. J. Paleontol. 45, 212–246 (1971).
Farrow, G. E. Bathymetric zonation of Jurassic trace fossils from the coast of Yorkshire, England. Palaeogeogr. Palaeoclimatol. Palaeoecol. 2, 103–151 (1966).
Mángano, M. G., Buatois, L. A., West, R. R. & Maples, C. G. Contrasting behavioral and feeding strategies recorded by tidal-flat bivalve trace fossils from the upper carboniferous of eastern Kansas. Palaios 13, 335–351 (1998).
Pemberton, S. G., Frey, R. W. & Bromley, R. G. The ichnotaxonomy of Conostichus and other plug-shaped ichnofossils. Can. J. Earth Sci. 25, 866–892 (1988).
Nara, M. Rosselia socialis: A dwelling structure of a probable terebellid polychaete. Lethaia 28, 171–178 (1995).
Wilson, M. A., Curran, H. A. & White, B. Paleontological evidence of a brief global sea-level event during the last interglacial. Lethaia 31, 241–250 (1998).
Santos, A., Mayoral, E., Marques da Silva, C., Cachão, M. & Kullberg, J. C. Trypanites ichnofacies: Palaeoenvironmental and tectonic implications. A case study from the Miocene disconformity at Foz da Fonte (Lower Tagus Basin, Portugal). Palaeogeogr. Palaeoclimatol. Palaeoecol. 292, 35–43 (2010).
Wilson, J. L. Carbonate Facies in Geological History (Springer, 1975).
Tucker, M. E. & Wright, V. P. Carbonate Sedimentology (Blackwell Science, 1990).
MacEachern, J. A. & Gingras, M. K. Recognition of brackish-water trace fossil assemblages in the Cretaceous western interior seaway of Alberta. In Sediment-Organism Interactions: A Multifaceted Ichnology (eds Bromley, R. G. et al.) 149–194 (Society for Sedimentary Geology Special Publication, 2007).
MacEachern, J. A., Zaitlin, B. A. & Pemberton, S. G. High-resolution sequence stratigraphy of early transgressive deposits, Viking Formation, Joffre Field, Alberta, Canada. Bull. Am. Assoc. Petrol. Geol. 82, 729–756 (1998).
Buatois, L. A., Netto, R. G. & Mángano, M. G. Ichnology of Permian marginal-marine to shallow-marine coal-bearing successions: Rio Bonito and Palermo formations, Parana Basin, Brazil. In Applied Ichnology (eds MacEachern, J. A. et al.) 167–177 (Society for Sedimentary Geology Short Course Notes, 2007).
Buatois, L. A. et al. Colonization of brackish-water systems through time: Evidence from the trace-fossil record. Palaios 20, 321–347 (2005).
Pemberton, S. G. & Wightman, D. M. Ichnological characteristics of brackish water deposits. In Applications of Ichnology to Petroleum Exploration: A Core Work-shop (ed. Pemberton, S. G.) 141–167 (Society of Economic Paleontologists and Mineralogists Core Workshop, 1992).
Anderson, B. G. & Droser, M. L. Ichnofabrics and geometric configurations of Ophiomorpha within a sequence stratigraphic framework: An example from the Upper Cretaceous US western interior. Sedimentology 45, 379–396 (1998).
Buatois, L. A., Mángano, M. G. & Pattison, S. A. J. Ichnology of prodeltaic hyperpycnite–turbidite channel complexes and lobes from the Upper Cretaceous Prairie Canyon Member of the Mancos Shale, Book Cliffs, Utah, USA. Sedimentology 66, 1825–1860 (2019).
Bhattacharya, J. P. & MacEachern, J. A. Hyperpycnal rivers and prodeltaic shelves in the Cretaceous seaway of North America. J. Sediment. Res. 79, 184–209 (2009).
Savrda, C. E. Ichnosedimentologic evidence for a noncatastrophic origin of Cretaceous-Tertiary boundary sand in Alabama. Geology 21, 1075–1078 (1993).
Schlager, W. Accommodation and supply-a dual control on stratigraphic sequences. Sediment. Geol. 86, 111–136 (1993).
Strasser, A. & Samankassou, E. Carbonate sedimentation rates today and in the past: Holocene of Florida Bay, Bahamas, and Bermuda vs. Upper Jurassic and Lower Cretaceous of the Jura Mountains (Switzerland and France). Geol. Croat. 56, 1–18 (2003).
Moyano-Paz, D., Richiano, S., Varela, A. N., Gómez-Dacal, A. R. & Poire, D. G. Ichnological signatures from wave- and fluvial-dominated deltas: The La Anita Fromation, Upper Cretaceous, Austral-Magallanes Basin, Patagonia. Mar. Pet. Geol. 114, 104168 (2020).
De Gibert, J. M. & Ekdale, A. A. Trace fossil assemblages reflecting stressed environments in the Middle Jurassic Carmel Seaway of Central Utah. J. Paleontol. 73, 711–720 (1999).
Gingras, M. K., MacEachern, J. A. & Dashtgard, S. E. Process ichnology and the elucidation of physico-chemical stress. Sediment. Geol. 237, 115–134 (2011).
Smith, C. R., Levin, L. A., Hoover, D. J., McMurty, G. & Gage, J. D. Variations in bioturbation across the oxygen minimum zone in the northwest Arabian Sea. Deep-Sea Res. II 47, 227–257 (2000).
Wignall, P. B., Newton, R. & Brookfield, M. E. Pyrite framboid evidence for oxygen-poor deposition during the Permian-Triassic crisis in Kashmir. Palaeogeogr. Palaeoclimatol. Palaeoecol. 216, 183–188 (2005).
Kennedy, W. J. Burrows and surface traces from the Lower Chalk of southern England. Bull. Br. Mus. Nat. Hist. Geol. 15, 127–167 (1967).
Kennedy, W. J. & Garrison, R. E. Morphology and genesis of nodular chalks and hardgrounds in the Upper Cretaceous of southern England. Sedimentology 22, 311–386 (1975).
Bromley, R. G. Some observations on burrows of thalassinidean Crustacea in chalk hardgrounds. Geol. Soc. Lond. Q. J. 123, 157–182 (1967).
Bromley, R. G. Trace fossils at omission surfaces. In The Study of Trace Fossils (ed. Frey, R. W.) 399–428 (Springer, 1975).
Hart, M. B., Harries, P. J. & Cárdenas, A. L. The Cretaceous/Paleogene boundary events in the Gulf Coast: Comparisons between Alabama and Texas. Gulf Coast Assoc. Geol. Trans. 63, 235–255 (2013).
Al Balushi, S. A. K. & Macquaker, J. H. S. Sedimentological evidence for bottom-water oxygenation during deposition of the Natih-B Member intrashelf-basinal sediments: Upper Cretaceous carbonate source rock, Natih Formation, North Sultanate of Oman. GeoArabia 16, 47–84 (2011).
Lasseur, E. et al. A relative water-depth model for the Normandy Chalk (Cenomanian–Middle Coniacian, Paris Basin, France) based on facies patterns of metre-scale cycles. Sediment. Geol. 213, 1–26 (2009).
Dawson, W. C. & Reaser, D. F. Rhizocorallium in the upper Austin Chalk, Ellis County, Texas. Texas J. of Sci. 23, 207–214 (1980).
Dawson, W. C. & Reaser, D. F. Ichnology and paleoenvironments of the middle and upper Austin Chalk (Upper Cretaceous), northeastern Texas. Trans. Am. Assoc. Pet. Geol. Southwest Sec. 1985, 47–67 (1985).
Dawson, W. C. & Reaser, D. F. Trace fossils and paleoenvironments of lower and middle Austin Chalk (Upper Cretaceous), north-central Texas. Trans. Gulf Coast Assoc. Geol. Soc. 40, 161–173 (1990).
Dawson, W. C. & Reaser, D. F. Ichnology and Paleosubstrates of Austin Chalk (Cretaceous) Outcrops: Southern Dallas and Ellis Counties, Texas. Am. Assoc. Pet. Geol. Search Discovery Article #91004 (1991).
Fürsich, F. T., Kennedy, W. J. & Palmer, T. J. Trace fossils at a regional discontinuity surface: The Austin/Taylor (Upper Cretaceous) contact in central Texas. J. Paleontol. 55, 537–551 (1981).
Morgan, R. F. A new ichnospecies of Gyrolithes from the Austin Chalk, Upper Cretaceous, Texas, USA. Ichnos 26, 1–7 (2018).
Cooper, J. R., Godet, A. & Pope, M. C. Tectonic and eustatic impact on depositional features in the upper Cretaceous Austin Chalk Group of south-central Texas, USA. Sediment. Geol. 401, 105632 (2020).
Loucks, R. G. et al. Geologic characterization of the type cored section for the Upper Cretaceous Austin Chalk Group in southern Texas: A combination fractured and unconventional reservoir. Am. Assoc. Pet. Geol. Bull. 104, 2209–2245 (2020).
Loucks, R. G., Reed, R. M., Ko, L. T., Zahm, C. K. & Larson, T. E. Micropetrographic characterization of a siliciclastic-rich chalk; Upper Cretaceous Austin Chalk Group along the onshore northern Gulf of Mexico, USA. Sediment. Geol. 412, 105821 (2021).
Bottjer, D. J. Paleoecology, Ichnology, and Depositional Environments of Upper Cretaceous Chalks (Annona Formation; chalk Member of Saratoga Formation), Southwestern Arkansas. PhD Dissertation, Indiana University, 424 (1978).
Bottjer, D. J. Ichnology and depositional environments of Upper Cretaceous chalks, southwestern Arkansas (Annona Formation; chalk member, Saratoga Formation). Am. Assoc. Pet. Geol. Bull. 63, 422 (1979).
Bottjer, D. J. Trace fossils and paleoenvironments of two Arkansas Upper Cretaceous discontinuity surfaces. J. Paleontol. 59, 282–298 (1985).
Bottjer, D. J. Campanian-Maastrichtian chalks of southwestern Arkansas: Petrology, paleoenvironments and comparison with other North American and European chalks. Cretac. Res. 7, 161–196 (1986).
Bayet-Goll, A., Neto de Carvalho, C., Monaco, P. & Sharafi, M. Sequence stratigraphic and sedimentologic significance of biogenic structures from chalky limestones of the Turonian-Campanian Abderaz Formation, Kopet-Dagh, Iran. In Cretaceous Period: Biotic Diversity and Biogeography (eds Khosla, A. & Lucas, S. G.) 19–43 (New Mex. Mus. Nat. His. Sci. Bull. 71, 2016).
Locklair, R. E. & Savrda, C. E. Ichnology of rhythmically bedded Demopolis Chalk (Upper Cretaceous, Alabama): Implications for paleoenvironment, depositional cycle origins, and tracemaker behavior. Palaios 13, 423–438 (1998).
Locklair, R. E. & Savrda, C. E. Ichnofossil tiering analysis of a rhythmically bedded chalk-marl sequence in the Upper Cretaceous of Alabama. Lethaia 31, 311–322 (1998).
Kennedy, W. J. Trace fossils in the chalk environment. In Trace Fossils (eds Crimes, T. P. & Harper, J. C.) 263–282 (Geological Journal Special Issue 3, 1970).
Mortimore, R. N. & Pomerol, B. Stratigraphy and eustatic implications of trace fossil events in the Upper Cretaceous Chalk of northern Europe. Palaios 6, 216–231 (1991).
Foster, C. B. III. Geology of the Moscow Landing Section, Tombigbee River, Western Alabama, with Focus on Ichnologic Aspects of the Lower Paleocene Clayton Formation. M.Sc. Dissertation, Auburn University, 88 (2019).
Gabdullin, R. R. Rhythmicity of the Upper Cretaceous Deposits of the East European Craton, Northwestern Caucasus and Southwestern Crimea: Structure, Classification, Formation Models (Mosk. Gos. Univ., 2002).
Baraboshkin, E. Y. & Zibrov, I. A. Characteristics of the Middle Cenomanian Rhythmic Sequence from Mount Selbukhra in Southwest Crimea. Moscow Univ. Geol. Bull. 67, 176–184 (2012).
Blinkenberg, K. H., Lauridsen, B. W., Knaust, D. & Stemmerik, L. New ichnofabrics of the Cenomanian-Danian Chalk Group. J. Sediment. Res. 90, 701–712 (2020).
Ekdale, A. A. & Bromley, R. G. Trace fossils and ichnofabric in the Kjolby Gaard Marl, uppermost Cretaceous, Denmark. Bull. Geol. Soc. Denmark 31, 107–119 (1983).
Ekdale, A. A. & Bromley, R. G. Cretaceous chalk ichnofacies in northern Europe. Geobios 8, 201–204 (1984).
Ekdale, A. A. & Bromley, R. G. Analysis of composite ichnofabrics; An example in Uppermost Cretaceous chalk of Denmark. Palaios 6, 232–249 (1991).
Surlyk, F. et al. The cyclic Rørdal Member—A new lithostratigraphic unit of chronostratigraphic and palaeoclimatic importance in the upper Maastrichtian of Denmark. Bull. Geol. Soc. Denmark 58, 89–98 (2010).
Lauridsen, B. W., Surlyk, F. & Bromley, R. G. Trace fossils of a cyclic chalk marl succession; the upper Maastrichtian Rørdal Member, Denamrk. Cretac. Res. 32, 194–211 (2011).
Frey, R. W. Trace fossils of Fort Hays Limestone Member of Niobrara Chalk (Upper Cretaceous), west-central Kansas. Univ. Kansas Paleontol. Contrib. 53, 52 (1970).
Hattin, D. E. Stratigraphy and depositional environment of Smoky Hill Chalk Member, Niobrara Chalk (Upper Cretaceous) of the type area western Kansas. Kansas Geol. Surv. Bull. 225, 1–108 (1982).
Savrda, C. E. Ichnocoenoses in the Niobrara Formation: Implications for benthic oxygenation histories. In Stratigraphy and Paleoenvironments of the Cretaceous Western Interior Seaway, USA (eds Dean, W. E. & Arthur, M. A.) 137–151 (SEPM Society for Sedimentary Geology 6, 1998).
Hattin, D. E. Widespread, synchronously deposited, burrow-mottled limestone beds in Greenhorn Limestone (Upper Cretaceous) of Kansas and southeastern Colorado. Am. Assoc. Pet. Geol. Bull. 55, 412–431 (1971).
Hattin, D. E. Stratigraphy and depositional environment of Greenhorn Limestone (Upper Cretaceous) of Kansas. Kansas Geol. Surv. Bull. 209, 128 (1975).
Savrda, C. E. Ichnology of the Bridge Creek Limestone: Evidence for temporal and spatial variations in paleo-oxygenation in the Western Interior Seaway. In Stratigraphy and Paleoenvironments of the Cretaceous Western Interior Seaway, USA (eds Dean, W. E. & Arthur, M. A.) 127–136 (SEPM Society for Sedimentary Geology 6, 1998).
Rasmussen, S. L. & Surlyk, F. Facies and ichnology of an Upper Cretaceous chalk contourite drift complex, eastern Denmark, and the validity of contourite facies models. J. Geol. Soc. Lond. 169, 435–447 (2012).
Surlyk, F. et al. Upper Campanian-Maastrichtian holostratigraphy of the eastern Danish Basin. Cretac. Res. 46, 232–256 (2013).
Boussaha, M., Thibault, N., Anderskouv, K., Moreau, J. & Stemmerik, L. Controls on upper Campanian-Maastrichtian chalk deposition in the eastern Danish Basin. Sedimentology 64, 1998–2030 (2017).
Reolid, J. & Betzler, C. The ichnology of carbonate drifts. Sedimentology 66, 1427–1448 (2019).
Nygaard, E. Bathichnus and Its Significance in the Trace Fossil Association of Upper Cretaceous Chalk, Mors, Denmark 107–113 (Danm. Geol. Unders. Årbog, 1983).
Scholle, P. A., Albrechtsen, T. & Tirsgaard, H. Formation and diagenesis of bedding cycles in uppermost Cretaceous chalks of the Dan Field, Danish North Sea. Sedimentology 45, 223–243 (1998).
Damholt, T. & Surlyk, F. Laminated–bioturbated cycles in Maastrichtian chalk of the North Sea: Oxygenation fluctuations within the Milankovitch frequency band. Sedimentology 51, 1323–1342 (2004).
Anderskouv, K. & Surlyk, F. Upper Cretaceous chalk facies and depositional history recorded in the Mona-1 core, Mona Ridge, Danish North Sea. Geol. Surv. Denmark Greenland Bull. 25, 1–60 (2011).
Maliva, R. G. & Dickson, J. A. D. Microfacies and diagenetic controls of porosity in Cretaceous/Tertiary chalks, Eldfisk Field, Norwegian North Sea. Am. Assoc. Pet. Geol. Bull. 76, 1825–1838 (1992).
Knaust, D., Dorador, J. & Rodríguez-Tovar, F. J. Burrowed matrix powering dual porosity systems—A case study from the Maastrichtian chalk of the Gullfaks Field Norwegian North Sea. Mar. Petrol. Geol. 113, 104158 (2020).
Phillips, C. & McIlroy, D. Ichnofabrics and biologically mediated changes in clay mineral assemblages from a deep-water, fine-grained, calcareous sedimentary succession: An example from the Upper Cretaceous Wyandot Formation, offshore Nova Scotia. Bull. Can. Petrol. Geol. 58, 203–218 (2010).
Rodríguez-Tovar, F. J. & Hernández-Molina, F. J. Ichnological analysis of contourites: Past, present and future. Earth-Sci. Rev. 182, 28–41 (2018).
Miguez-Salas, O. & Rodríguez-Tovar, F. J. Ichnofacies distribution in the Eocene-Early Miocene Petra Tou Romiou outcrop, Cyprus: Sea level dynamics and palaeoenvironmental implications in a contourite environment. Int. J. Earth Sci. 108, 2531–2544 (2019).
Nelson, C. S. Bioturbation in middle bathyal, Cenozoic nannofossil oozes and chalks, southwest Pacific. In Initial Reports of the Deep Sea Drilling Project 90 (eds Kennett, J. P., von der Borch, C. C. et al.) 1189–1200 (Washington U.S. Government Printing Office, 1986).
Fütterer, D. K. Bioturbation and trace fossils in deep sea sediments of the Walvis Ridge, southeastern Atlantic, Leg 74. In Initial Reports of the Deep Sea Drilling Project 74 (eds Moore, T. C., Rabinowitz, P. D. et al.) 543–555 (Government Printing Office, 1984).
Wetzel, A. Ichnofabrics in Eocene to Maestrichtian sediments from Deep Sea Drilling Project Site 605, off the New Jersey coast. In Initial Reports of the Deep Sea Drilling Project 93 (eds. Hinte, J. E., Wise Jr., S. W. et al.) 825–835 (1987).
Droser, M. L. & Bottjer, D. J. Trace fossils and ichnofabrics in Leg 119 cores. In Proceedings of the Ocean Drilling Program, Scientific Results 119 (eds. Barron, J., Larsen, B. et al.) 635–641 (1991).
Desai, B. G. Ichnofabric analysis of bathyal chalks: The Miocene Inglis Formation of the Andaman and Nicobar Islands, India. J. Palaeogeogr. 10, 1–15 (2021).
Warme, J. E., Kennedy, W. J. & Scheidermann, N. Biogenic sedimentary structures (trace fossils) in Leg 15 cores. In Initial Reports of the Deep Sea Drilling Project 15 (eds. Edgar, N. T., Saunders, J. B. et al.) 813–831 (1973).
Maurrasse, F. Sedimentary structures of Caribbean Leg 15 sediments. In Initial Reports of the Deep-Sea Drilling Project 15 (eds. Edgar, T. et al.) (1974).
Erba, E. & Premoli-Silva, I. Orbitally driven cycles in trace-fossil distribution from the Piobbico core (late Albian, central Italy). In Orbital Forcing and Cyclic Sequences, IAS Spec. Publ. 19 (eds De Boer, P. L. & Smith, D. G.) 211–225 (Blackwell Scientific, 1994).
Chamberlain, C. K. Trace fossils in DSDP cores of the Pacific. J. Paleontol. 49, 1074–1096 (1975).
Ekdale, A. A. Trace fossils in Deep Sea Drilling Project Leg 58 cores. In Initial Reports of the Deep Sea Drilling Project 58 (eds. de Vries Klein, G., Kobyashi, K. et al.) 601–605 (1980).
Ekdale, A. A. Geologic history of the abyssal benthos: Evidence from trace fossils in Deep-Sea Drilling Project cores. PhD Dissertation, Rice University, 154 (1974).
Ekdale, A. A. Abyssal trace fossils in worldwide Deep Sea Drilling Project cores. In Trace Fossils 2 (eds. Crimes, T. P. & Harper, J. C.) 163–182 (Geol. J., Spec. Iss. 9, 1977).
Ekdale, A. A. & Berger, W. H. Deep-sea ichnofacies: Modern organism traces on and in pelagic carbonates of the western equatorial Pacific. Palaeogeogr. Palaeoclimatol. Palaeoecol. 23, 263–278 (1978).
Ekdale, A. A., Muller, L. N. & Novak, M. T. Quantitative ichnology of modern pelagic deposits in the abyssal Atlantic. Palaeogeogr. Palaeoclimatol. Palaeoecol. 45, 189–223 (1984).
Savrda, C. E. Limited ichnologic fidelity and temporal resolution in pelagic sediments: Paleoenvironmental and paleoecologic implications. Palaios 29, 210–217 (2014).
Bromley, R. G. & Ekdale, A. A. Composite ichnofabrics and tiering of burrows. Geol. Mag. 123, 59–65 (1986).
Griffin, J. N. et al. Spatial heterogeneity increases the importance of species richness for an ecosystem process. Oikos 118, 1335–1342 (2009).
Valentine, J. W. Overview of marine biodiversity. In Marine Macroecology (eds Witman, J. D. & Roy, K.) 3–28 (University of Chicago Press, 2009).
Schlacher, T. A. et al. Soft-sediment benthic community structure in a coral reef lagoon—The prominence of spatial heterogeneity and “spot endemism”. Mar. Ecol. Prog. Ser. 174, 159–174 (1998).
Hummel, H. et al. Geographic patterns of biodiversity in European coastal marine benthos. J. Mar. Biol. Assoc. U.K. 97, 507–523 (2017).
Harborne, A. R., Mumby, P. J., Żychaluk, K., Hedley, J. D. & Blackwell, P. G. Modeling the beta diversity of coral reefs. Ecology 87, 2871–2881 (2006).
Christia, C., Giordani, G. & Papastergiadou, E. Environmental variability and macrophyte assemblages in coastal lagoon types of Western Greece (Mediterranean Sea). Water 10, 151 (2018).
Dorador, J., Rodríguez-Tovar, F. J., IODP Expedition 339 Scientists. Digital image treatment applied to ichnological analysis of marine core sediments. Facies 60, 39–44 (2014).
Dorador, J. & Rodríguez-Tovar, F. J. High-resolution image treatment in ichnological core analysis: Initial steps, advances and prospects. Earth-Sci. Rev. 177, 226–237 (2018).
Taylor, A. M. & Goldring, R. Description and analysis of bioturbation and ichnofabric. J. Geol. Soc. 150, 141–148 (1993).
Cao, Y. M., Curran, A. H. & Glumac, B. Testing the use of photoshop and imageJ for evaluating ichnofabrics. 2015 GSA Annual Meeting in Baltimore, Maryland, USA, Paper No. 128-11 (The Geol. Soc. of Am., 2015).
Acknowledgements
We thank Alfred Uchman for valuable feedback on echinoid trace fossils and Mark Wilson for his comments on bioerosion structures. This manuscript has benefited from valuable feedback from anonymous reviewers and the Scientific Reports editors. This work was financially supported by the University of Saskatchewan, the American Association of Petroleum Geologists, the Canadian Society of Petroleum Geologists, and Cenovus Energy Inc. (scholarships awarded to Valencia), as well as by funding from the Natural Sciences and Engineering Research Council of Canada (NSERC) Discovery Grants 311727-20 and 422931-20 awarded to Mángano and Buatois, respectively. Mángano also thanks funding from the George J. McLeod Enhancement Chair in Geology.
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F.L.V. and J.C.L. performed the fieldwork. F.L.V., M.G.M. and L.A.B. wrote the main manuscript text and F.L.V. prepared all figures, tables, and supplementary material. All authors reviewed the manuscript.
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Valencia, F.L., Mángano, M.G., Buatois, L.A. et al. Animal–substrate interactions preserved in ancient lagoonal chalk. Sci Rep 12, 14383 (2022). https://doi.org/10.1038/s41598-022-18713-8
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DOI: https://doi.org/10.1038/s41598-022-18713-8
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