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Thanetian
Thanetian
Thanetian
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Thanetian
59.24 – 56.00 Ma
Chronology
−70 —
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−55 —
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MZ
 
First Antarctic permanent ice-sheets[1]
Subdivision of the Paleogene according to the ICS, as of 2024.[2]
Vertical axis scale: Millions of years ago
Formerly part ofTertiary Period/System
Etymology
Name formalityFormal
Usage information
Celestial bodyEarth
Regional usageGlobal (ICS)
Time scale(s) usedICS Time Scale
Definition
Chronological unitAge
Stratigraphic unitStage
Time span formalityFormal
Lower boundary definitionBase of magnetic polarity chronozone C26n
Lower boundary GSSPZumaia Section, Basque Country, Spain
43°17′59″N 2°15′39″W / 43.2996°N 2.2609°W / 43.2996; -2.2609
Lower GSSP ratified2008[3]
Upper boundary definitionStrong negative anomaly in δ13C values at the PETM[4]
Upper boundary GSSPDababiya section, Luxor, Egypt[4]
25°30′00″N 32°31′52″E / 25.5000°N 32.5311°E / 25.5000; 32.5311
Upper GSSP ratified2003[4]

The Thanetian is, in the ICS Geologic timescale, the latest age or uppermost stratigraphic stage of the Paleocene Epoch or Series. It spans the time between 59.24 and 56 Ma. The Thanetian is preceded by the Selandian Age and followed by the Ypresian Age (part of the Eocene).[5] The Thanetian is sometimes referred to as the Late Paleocene.

Stratigraphic definition

[edit]

The Thanetian was established by Swiss geologist Eugène Renevier in 1873. The Thanetian is named after the Thanet Formation, the oldest Cenozoic deposit of the London Basin, which was first identified in the area of Kent (southern England) known as the Isle of Thanet.

The base of the Thanetian Stage is laid at the base of magnetic chronozone C26n. The references profile (Global Boundary Stratotype Section and Point) is in the Zumaia section (43° 18'N, 2° 16'W) at the beach of Itzurun, Pais Vasco, northern Spain.[6] Fossils of the unicellular planktonic marine coccolithophore Areoligeria gippingensis make their first appearance at the base of the Thanetian, and help define its lowest stratigraphic boundary.

The top of the Thanetian Stage (the base of the Ypresian) is defined at a strong negative anomaly in δ13C values at the global thermal maximum at the Paleocene-Eocene boundary.

The Thanetian Stage is coeval the lower Neustrian European land mammal age (it spans the Mammal Paleogene zone 6 and part of zones 1 through 5.[7]), the upper Tiffanian and Clarkforkian North American land mammal ages, the Riochican and part of the Itaboraian South American land mammal ages and the upper Nongshanian and Gashatan Asian land mammal ages. The Thanetian is contemporary with the middle Wangerripian regional stage of Australia and the upper Ynezian regional stage of California. It overlaps the obsolete regional stages Landenian and Heersian of Belgium.

Palaeontology

[edit]

The Sézanne flora is a fossil assemblage preserved in freshwater limestone deposits at Sézanne, laid down during the Thanetian Age, when Europe enjoyed a tropical climate. In the lagerstätte, leaves, entire flowers and seeds are minutely preserved. Also, the first representatives of Proboscidea appeared, Eritherium.[8]

Climate

[edit]

This period was characterized by temperatures warmer than those of today.[9]

See also

[edit]

References

[edit]
[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Thanetian

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The Thanetian is the uppermost stage of the Epoch in the Period of the , representing the final interval of the from 59.24 to 56.00 million years ago. Named after the Thanet Sands Formation exposed on of Thanet in southeast , it follows the Stage and precedes the Ypresian Stage of the Eocene Epoch. The stage is characterized by marine and terrestrial deposits worldwide, including key formations such as the Thanet Sands and Upnor Formations in , and the Sheterat and Zaltan/Upper Sabil Limestones in the Sirt Basin of . The base of the Thanetian is defined by the Global Stratotype Section and Point (GSSP) at Itzurun Beach in , Basque Country, northern (coordinates: 43° 17' 58.4" N, 2° 15' 39.1" W), located about 78 meters above the Cretaceous-Paleogene boundary. This boundary is marked by the base of magnetic polarity chronozone C26n, coinciding with 2.8 meters (eight precession cycles) above the base of the clay-rich interval associated with the Mid-Paleocene Biotic Event (MPBE), without significant changes in marine microfossils. The top of the stage corresponds to the Paleocene-Eocene boundary, defined elsewhere by the base of the Ypresian at the onset of the Paleocene-Eocene Thermal Maximum (PETM), a major global warming event. During the Thanetian, experienced a general warming trend within the broader greenhouse climate, with evidence of tropical conditions in parts of , as indicated by floras like the Sézanne assemblage preserved in freshwater limestones of . Biostratigraphically, the stage encompasses calcareous nannofossil zones NP6 to NP9 and dinoflagellate cyst zones Viborg 3 to 6, reflecting diverse marine assemblages. Notable fossils include the early giant bird in and a variety of in North American deposits, highlighting faunal diversification in coastal and inland environments. The Selandian-Thanetian transition features environmental shifts, including increased warmth and oligotrophic marine conditions, linked to perturbations and biotic turnovers in the region. Overall, the Thanetian records the culmination of recovery from the end-Cretaceous extinction, setting the stage for Eocene diversification.

Definition and nomenclature

Etymology and historical establishment

The name "Thanetian" derives from the Thanet Formation, also known as the Thanet Sands, a sequence of predominantly fine- to medium-grained, glauconitic sandy deposits exposed on the in southeast . These sediments represent shallow-marine lithologies that form the type area for the uppermost , with the formation's name originally coined by geologist Joseph Prestwich in 1852 based on exposures at . The Thanetian stage was first proposed in 1873 by Swiss geologist Eugène Renevier as part of his stratigraphic scheme for the Tertiary terrains of the and surrounding regions. In his publication Tableau des terrains sédimentaires formés pendant les époques de la phase organique du globe terrestre, Renevier defined the Thanetian to encompass the uppermost , initially including the Thanet Sands (with the index Cyprina morrisi) along with the overlying and Reading Beds (characterized by Cyrena cuneata) in . This proposal integrated British lithostratigraphic units into a broader European framework, drawing on earlier descriptions by (1852) and William Whitaker (1866, 1872), who had detailed the Thanet Beds' varied sandy and shelly compositions at key sites like and . Initially applied in regional European contexts to denote the latest Paleocene rocks, the Thanetian gained traction through refinements in , particularly after French Gustave Dollfus restricted its scope in 1880 to the Thanet Sands alone, excluding the and Reading Beds. In French , Dollfus's definition (Bulletin de la Société Géologique de Normandie, 6:584–605) facilitated correlations with Parisian Basin sequences, while in British usage, the stage was adopted more widely by the early , with sites like designated as the type section and as a co-stratotype by the mid-20th century. This evolution from a regional Alpine and Anglo-French term to a standardized global stage occurred through international geological commissions by the mid-20th century, reflecting broader harmonization of .

Global Stratotype Section and Point (GSSP)

The Global Stratotype Section and Point (GSSP) for the base of the Stage is situated in the sea-cliff exposures at Itzurun Beach, , in the Basque Country of northern , at coordinates 43.2996°N, 2.2609°W. This location forms part of the continuous Itzurun section within the Itzurun Formation, positioned approximately 78 m above the Cretaceous-Paleogene boundary and about 29 m above the base of the underlying Stage. The site's exceptional preservation and accessibility, combined with its well-exposed hemipelagic deposits, make it an ideal reference for international correlation. The GSSP was formally proposed by the Paleocene Working Group of the International Subcommission on Paleogene Stratigraphy and ratified by the in June 2008, with final approval by the on September 23, 2008. This ratification established the section as the definitive global reference for the lower boundary of the Thanetian, emphasizing its integrated stratigraphic record that includes high-resolution , cyclostratigraphy, and . The primary defining criterion is the base of magnetic polarity chronozone C26n, corresponding to the C26r/C26n reversal, which is dated to approximately 59.24 Ma based on radioisotopic and astronomical tuning. Auxiliary markers support the primary magnetostratigraphic boundary, including the position 2.8 m (equivalent to eight cycles) above the base of the clay-rich Mid-Paleocene Biotic Event interval. The lithological context features alternating hemipelagic marls and limestones of the Itzurun Formation, with the lower Member A dominated by siliciclastic turbidites and marls transitioning to mixed siliciclastic-carbonatic deposits in Member B, reflecting deep-marine without significant hiatuses or tectonic disruptions. Biostratigraphically, the stage encompasses nannofossil zones NP6 to NP9, particularly in nannofossil NP6.

Stratigraphy

Boundaries

The lower boundary of the Thanetian stage marks the transition from the underlying stage and coincides with the base of magnetic polarity chronozone C26n at approximately 59.2 Ma. This boundary is defined primarily through , with supporting biostratigraphic markers including the first occurrence of the dinoflagellate cyst Areoligera gippingensis and the absence of certain Selandian-index dinoflagellate cysts such as Alisocysta circumantiqua. The boundary lacks a major calcareous nannofossil turnover. The upper boundary of the Thanetian stage corresponds to the Paleocene-Eocene boundary at approximately 56 Ma, defined by the onset of the negative carbon isotope excursion (CIE) associated with the Paleocene-Eocene Thermal Maximum (PETM). This boundary's Global Stratotype Section and Point (GSSP) is located at the Dababiya section in , within the , where it is placed at the base of a distinctive clay layer recording the CIE initiation. Boundary determination integrates (e.g., placement within chron C24r for the upper limit), chemostratigraphy via δ¹³C analysis of carbonates and organics to identify the CIE, and including foraminiferal and nannofossil turnovers. The total duration of the Thanetian stage, between these boundaries, is approximately 3.2 million years. Transitional features at the lower boundary include a gradual faunal turnover linked to the Selandian-Thanetian Transition Event (STTE), involving shifts in benthic and cyst assemblages indicative of environmental changes toward warmer conditions. At the upper boundary, the PETM onset features abrupt global warming of 5–8°C and associated benthic extinctions, particularly among deep-sea , driven by and hypoxia.

Subdivisions and correlation

The Thanetian stage is informally subdivided into lower, middle, and upper parts primarily based on nannofossil biozonation schemes, encompassing Zones NP6 to NP9, with NP6 and NP7 (often combined as NP6/7) in the lowermost part, NP8 in the lower to middle, and NP9 in the upper. Zone NP8 is defined by the first occurrence (FO) of Heliolithus riedelii to the FO of Discoaster multiradiatus, while Zone NP9 spans from the FO of D. multiradiatus to the FO of Tribrachiatus actius. In some regional schemes, Zone NP9 is further divided into subzones NP9a (marked by the FO of Fasciculithus thomasii) and NP9b (up to the FO of Rhomboaster calcarus), providing finer resolution in Tethyan sections. These subdivisions reflect evolutionary turnover in nannofossil assemblages and are used to delineate informal substages, such as in European (e.g., ) versus Tethyan (e.g., Italian) stratigraphic frameworks, where the lower part aligns with coarser siliciclastic deposits and the upper with more carbonate-rich sequences. Correlation of the Thanetian across global records relies primarily on calcareous nannoplankton biozones, supplemented by planktonic foraminiferal zones and magnetic polarity chrons. The key nannofossil markers include the FO of H. riedelii at the base of NP8 and the FO of D. multiradiatus marking the NP8/NP9 boundary, which provide high-resolution ties in open-marine settings. Planktonic foraminiferal biozones, such as the upper part of Zone P4 (Globanomalina pseudomenardii) for the lower Thanetian and Zone P5 (Morozovella occlusa) for the upper, offer complementary correlation in tropical to subtropical sections, though they exhibit diachroneity due to provincialism. anchors these biostratigraphic events to polarity chrons C26n (base of the stage) through C25n (near the top), with the NP8/NP9 boundary falling within Chron C25r. Global correlation faces challenges from discrepancies between deep-sea (e.g., pelagic carbonates with complete nannofossil records) and shallow-marine (e.g., terrigenous clastics with hiatuses or condensed sections) deposits, leading to potential misalignment of boundaries by up to 0.5 million years. To address this, δ¹³C chemostratigraphy is employed, particularly to link Thanetian sequences to precursor events of the Paleocene-Eocene Thermal Maximum (PETM), such as the Mid-Paleocene Biotic Event negative excursion near the /Thanetian boundary, which shows consistent carbon isotope patterns across Tethyan and Atlantic sites. Regional correlations exemplify these methods; in the Basin, the Thanetian is recognized in the Thanet Formation and lower Group, where NP6/7 and NP8 span glauconitic sands and NP9 aligns with the base of the Shell Bed, tied to Chron C26n via . In the Tethyan domain, the Scaglia Rossa Formation in records the full Thanetian succession, with Zone NP8 in pink marly limestones and NP9 in hemipelagic marls, correlated to foraminiferal Zone P5 and δ¹³C shifts that match global patterns.

Paleogeography and environments

Tectonic and geographic configurations

During the Thanetian stage, the global tectonic configuration featured as a northern comprising , , , and , positioned across mid-to-high northern latitudes, while remnants of occupied southern latitudes, with separated from and continuing its northward drift as an independent plate. , having rifted from the northern margin of in the , reached paleolatitudes of approximately 13–14°N by this time, approaching the southern margin of and initiating the closure of the . Key tectonic events included ongoing rifting within the domain, driven by the northward motion of the Indian plate at rates exceeding 200 mm/year, which led to the initial collision between the Tethyan Himalaya terrane and the Lhasa block around 61 Ma, marking the precursor to the Himalayan through compressional deformation and crustal shortening. Along the Pacific margins, continued vigorously beneath the western edges of the and , contributing to Andean and circum-Pacific arc volcanism, while the proto-Atlantic experienced steady widening through . Ocean basin evolution was characterized by the incipient opening of the North Atlantic between and , with rifting along the East Greenland margin forming shallow seaways that connected to the Norwegian-Greenland Sea, though the full oceanic connection remained limited until the Eocene. The Tethys seaways became increasingly restricted due to the converging Indian and Eurasian plates, influencing regional ocean gateways, while in the south, initial separation of from via the region began around 62–59 Ma due to clockwise rotation of the , with land connections persisting until approximately 57 Ma and full deep-water circulation much later; remained connected to along its eastern margin until the mid-Eocene around 45 Ma. Paleolatitudinal distributions placed equatorial regions under the influence of the Indian and African plates, supporting expansive low-latitude landmasses, while high-latitude positions of and northern maintained polar connections conducive to global heat transport.

Sedimentary and sea-level patterns

The Thanetian stage featured diverse lithofacies that reflected a range of depositional settings, from shallow shelves to deep basins and continental interiors. Shallow-marine sands, rich in , characterized nearshore environments in northwest , as preserved in the Thanet Formation of southeastern , where fine- to medium-grained sands with flakes indicate deposition on a low-energy shelf during early to mid-Thanetian time. In the Tethyan domain, deep-sea carbonates dominated, including reddish pelagic limestones of the Scaglia Rossa Formation in the Umbria-Marche Basin of , which represent hemipelagic accumulation in bathyal settings with occasional chert interbeds derived from siliceous oozes. Terrestrial , formed in oxidizing alluvial plains, were widespread in , such as the continental sequences in southern and the Nanxiong Basin of , where reddish sandstones and mudstones signify fluvial and deposition under arid to semi-arid conditions. Sea-level patterns during the Thanetian showed regional transgressive trends without synchronous global-scale cycles, driven by eustatic variations superimposed on local . In many peri-Tethyan and Atlantic-margin basins, an overall rise in relative prevailed, culminating in a mid-Thanetian highstand that expanded shallow-marine realms, with third-order fluctuations estimated at tens of meters linked to thermal from incipient North Atlantic rifting. These changes are evidenced by sequence boundaries in sections like Gebel Matulla in Sinai, , where two transgressive-regressive parasequences mark the stage, beginning with a Selandian-Thanetian boundary flooding and ending near the Paleocene-Eocene transition. Regionally, epicontinental seas facilitated widespread shallow-marine sedimentation in and , with glauconitic sands and clays filling subsiding platforms in the London Basin and parts of the Midway Group in the Gulf Coast. In , deltaic systems prograded into coastal lows, as in the Cambay Basin where sediments of the Kalol Formation include lignitic shales and sandstones indicative of fluvial-deltaic input. Open-ocean realms accumulated hemipelagic oozes, such as coccolith-rich marls in the Tethys and emerging Atlantic, reflecting low-energy pelagic settling far from terrigenous sources. Key formations illustrate these patterns: the Thanet Formation in the UK, a sequence of glauconitic sands and clays, records nearshore to shelf deposition in the Anglo-Paris Basin. The Scaglia Rossa Formation in exemplifies Tethyan deep-water carbonates, with its well-stratified limestones spanning the stage in hemipelagic settings. In the US Gulf Coast, equivalents occur in the upper Midway Group, where interbedded sands and shales denote deltaic and shallow-marine influences during the Selandian-Thanetian transition.

Paleoclimate

Temperature and atmospheric conditions

The Thanetian stage, spanning approximately 59.2 to 56.0 million years ago, was characterized by a global significantly warmer than today, with an overall increase of about 5–10°C relative to modern conditions and a notably reduced latitudinal . Proxy reconstructions indicate annual temperatures (MAT) at mid-latitudes, such as in the of , ranged from 10.4°C to 12.5°C, derived from digital leaf physiognomy analysis of fossil floras. At high northern latitudes near 85°N in northern , MAT estimates from leaf margin analysis and vegetation proxies suggest values between 3°C and 13°C, reflecting a cool-temperate without severe winter freezes. Equatorial surface temperatures (SSTs), inferred from alkenone and other proxies, hovered around 30–35°C, contributing to the equable climate with minimal seasonal extremes. Atmospheric CO₂ levels during the Thanetian were elevated at 500–1000 ppm, primarily stable throughout much of the stage but showing a precursor rise toward the end in anticipation of the Paleocene-Eocene Thermal Maximum (PETM). These concentrations were reconstructed using stomatal indices from fossil leaves, which inversely correlate with atmospheric CO₂, and pedogenic carbonates, where carbon isotope ratios in soil nodules provide estimates of paleo-pCO₂. The higher CO₂ contributed to the greenhouse conditions, with global mean surface air temperatures around 21–22°C compared to modern values of about 15°C. margin analysis of Paleocene floras further supports these temperature profiles, as the proportion of untoothed leaves correlates positively with warmer , yielding consistent estimates across continental sites. Weather patterns in the Thanetian featured enhanced monsoonality in , driven by early tectonic uplift of the Himalayan-Tibetan region, which reached mean heights of 2300–2400 m by the late and acted as a barrier to dry continental air, promoting moisture influx from the . This uplift intensified seasonal precipitation, with modeled annual rainfall in exceeding 2000 mm in some areas, marking a transition toward modern-like dynamics. In contrast, mid-latitude continental interiors experienced arid conditions due to increased continentality and weakened moisture transport, as evidenced by sedimentological proxies indicating expanded dry zones. These patterns underscore the role of paleogeography in modulating regional under elevated greenhouse forcing.

Oceanic circulation and isotopic records

During the Thanetian stage, oceanic circulation exhibited relatively weak thermohaline components compared to modern configurations, influenced by the greenhouse climate and ongoing tectonic reconfiguration of ocean basins. Numerical modeling indicates that the Paleocene-Eocene ocean lacked strong reversed or poleward deep-water flow, with thermohaline circulation subdued due to reduced latitudinal temperature gradients and limited polar cooling. The Tethys Ocean functioned as a major mixing basin, facilitating the exchange and homogenization of warm surface waters from the proto-Indian and western Atlantic realms, though deep-water contributions from Tethys to adjacent basins were minimal owing to topographic barriers like the Indian continent and mid-ocean ridges. In the proto-North Atlantic, early development of gyre-like circulation began as the basin widened, with evidence of initial deep-water exchange through seaways, setting the stage for later intensification, as inferred from seismic and sedimentary records. Deep ocean waters during the Thanetian were generally oxic, supporting diverse benthic communities, particularly in open marine settings. Benthic foraminiferal assemblages from shallow Tethyan margins, such as those in the Western Desert of Egypt, show dominance of oxyphilic taxa like Cibicidoides and Cibicides, indicating well-ventilated bottom waters with no widespread anoxia. Trace metal analyses from mid-latitude eastern Indian Ocean sediments reveal primarily oxic conditions around 57 Ma, with redox-sensitive elements like Mo, U, and Ni showing low enrichment factors consistent with oxygenated bottom waters. However, brief suboxic to anoxic episodes occurred in restricted basins, such as marginal Tethyan sub-basins, where localized stratification and reduced ventilation led to transient hypoxia, evidenced by minor peaks in authigenic uranium and molybdenum during pre-hyperthermal fluctuations. Stable isotope records from benthic highlight persistently warm oceanic conditions throughout the Thanetian, with δ¹⁸O values reflecting bottom water temperatures of approximately 10–12°C globally, indicative of a low ice-volume, state. High-resolution records from the South Atlantic (ODP Site 1262) show orbitally paced δ¹⁸O variations of ~0.5‰ , superimposed on a long-term decrease toward the PETM, signaling gradual deep-water warming of ~2–4°C over eccentricity cycles. Carbon isotope (δ¹³C) profiles exhibit relative stability pre-PETM at around +0.5 to +1.2‰ in benthic , reflecting balanced global carbon cycling with minimal perturbations until the terminal Thanetian. Minor negative excursions of ~0.3–0.5‰ occurred on 100-kyr timescales, linked to enhanced marine productivity or regional , but overall values remained steady without major disruptions. Key geochemical proxies provide insights into Thanetian paleoceanography. Foraminiferal Mg/Ca ratios in planktonic species like Morozovella from tropical sites yield (SST) estimates of 30–32°C, confirming warm, equable surface waters with minimal seasonal variability, calibrated against modern exponential relationships (Mg/Ca = 0.38 exp(0.09 × T)). Benthic foraminiferal δ¹³C gradients between deep Atlantic and Pacific sites (~0.8–1.0‰) indicate efficient carbon export and remineralization in oxic deep waters, with values tracking global organic carbon burial rates and supporting a stable oceanic carbon reservoir prior to Eocene hyperthermals.

Paleontology and biodiversity

Marine biota

The marine biota of the Thanetian (59.2–56.0 Ma) exhibited a gradual diversification following the Cretaceous-Paleogene (K-Pg) extinction, with planktonic communities dominated by nannofossils that served as key biostratigraphic markers. nannofossils, particularly of the Fasciculithus such as F. tympaniformis and F. ulii, were abundant in open-ocean settings, reflecting enhanced calcification in warmer waters and contributing to the NP6 and NP7 nannofossil zones. These microfossils formed the primary component of pelagic sediments, with their first occurrences aiding in precise of Thanetian strata across Tethyan and Atlantic basins. In coastal zones, dinoflagellate cysts showed increased abundances, indicative of nutrient-rich environments that supported occasional blooms, as evidenced by diverse assemblages in marginal marine deposits from the Tethys region. Benthic and nektonic communities displayed notable recoveries, with undergoing diversification that underscored ecological stabilization post-extinction. Larger benthic , including early nummulitids like Nummulites luterbacheri, proliferated in shallow, photic-zone carbonates, forming bioherms in tropical platforms and marking a shift toward more complex shallow-water habitats. Planktonic exhibited rapid , particularly in tropical Pacific assemblages, with genera such as Globanomalina and Acarinina dominating surface waters and reflecting opportunistic of vacated niches. Among nektonic predators, elasmobranchs ( and rays) rediversified, with assemblages including squaliform and galeocerdids like Physogaleus onkensis in phosphatic lag deposits, indicating a return to diverse mid-trophic level predation in shelf seas. Molluscan faunas, including gastropods and bivalves, contributed to benthic diversity, though they remained less abundant than in carbonate-dominated settings. Thanetian marine ecosystems featured structured habitats that supported localized hotspots, particularly in tropical regions. Coral-algal reefs, constructed by scleractinian corals and coralline , developed on Tethyan platforms, though they were smaller and less extensive than pre-extinction structures due to , as seen in the Salt Mountain Limestone of . These reefs hosted symbiotic communities with and mollusks, fostering patch-reef growth in shallow, oligotrophic waters. In contrast, upwelling zones along continental margins, such as those inferred from high-productivity sediments in the South Atlantic, sustained diverse fish assemblages, including perciforms like Mene species, which thrived on enhanced nutrient fluxes and low-oxygen tolerant . Overall, the Thanetian marked a phase of incremental biotic recovery from the K-Pg extinction, with increased rates in open-ocean and shelf driving higher compared to the . This turnover involved opportunistic taxa filling ecological gaps, leading to more resilient marine communities by the stage's end, though full pre-extinction levels were not regained until the Eocene.

Terrestrial biota and evolutionary events

During the Thanetian, terrestrial ecosystems featured angiosperm-dominated forests indicative of a , with diverse , flower, and assemblages preserved in lacustrine deposits. The Sézanne from freshwater limestones in the , , exemplifies this, containing laurel-like leaves () and palm fronds suggestive of humid, lowland environments. Early diversification of the mangrove palm Nypa also occurred, with abundant and s recorded in coastal sediments from regions like western , , reflecting adaptation to brackish, swampy habitats near shorelines. Mammalian faunas underwent significant radiations on land, marking continued recovery from the K-Pg extinction. In , the earliest proboscideans, such as Eritherium azzouzorum from the Ouled Abdoun Basin, (ca. 60 Ma, latest ), appeared near the onset of the late , representing the basalmost member of the order with primitive dental features like low-crowned molars. In , multituberculates persisted as dominant small herbivores, with genera such as Hainina and Neoplagiaulax documented in European localities, exhibiting specialized cheek teeth for gnawing vegetation. Early perissodactyl precursors emerged among condylarth-like ungulates, showing adaptations toward odd-toed browsing that foreshadowed Eocene diversification. Key evolutionary milestones included the post-K-Pg biotic recovery, with placental mammals diversifying into modern orders through ecological release following dinosaur extinction, as evidenced by genomic and calibrations indicating continuous without major interruption. and reptiles maintained persistence in terrestrial niches, with crocodilians and co-occurring in mammal-bearing sites, while assemblages likely supported and roles in recovering forests, though specific Thanetian records remain sparse. Avian faunas included early neornithine birds such as galliforms and charadriiforms in European and North American localities, contributing to post-extinction diversification of modern bird lineages. Important fossil sites include the Cernay-le-Ville Conglomerate in , yielding a diverse late Thanetian mammal assemblage with over 20 of archaic ungulates, insectivores, and multituberculates, correlated to European reference level MP6. In , Tiffanian faunas from the Polecat Bench area in preserve similar radiations, including early carnivores and herbivores adapted to forested floodplains. Asian records, such as the Gashato Formation in , document early gliriform like Eurymylus, basal relatives of and lagomorphs, highlighting continental-scale mammalian turnover.

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