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Valanginian

The Valanginian is an age and stage of the Period/epoch in the , representing the second chronostratigraphic division of the Series after the Berriasian and before the . It spans approximately 4.45 million years, from its base at 137.05 ± 0.2 Ma to its top at 132.6 ± 0.6 Ma. The base of the Valanginian is formally defined by the Global Stratotype Section and Point (GSSP) located at the base of Bed VGL-B136 (19.23 m above the section base) in the Vergol section near Montbrun-les-Bains, department, southeastern (44°12'11''N, 5°25'03''E), where it coincides with the first occurrence of the ammonite Thurmanniceras pertransiens. The Valanginian is marked by hemipelagic marl-limestone alternations in reference sections such as those in the Vocontian Basin of , reflecting orbitally driven cyclicity with a duration calibrated to 5.08 million years based on 405-kyr eccentricity cycles. Biostratigraphically, it is subdivided into several ammonite zones, including the Thurmanniceras pertransiens, Busnardoites campylotoxus, and Saynoceras verrucosum zones, alongside calcareous nannofossil zones that aid global correlation. Lithologically, the stage features diverse marine sediments, such as sandstones in regions like , , and , and shales in and , indicative of varying depositional environments during a time of rising sea levels and platform development. A defining feature of the Valanginian is the Weissert Event, centered around 134 Ma in the upper part of the stage, which records a major perturbation of the global carbon cycle with a positive δ¹³C excursion of up to 2‰ in carbonates and 4‰ in organic matter, accompanied by transient cooling, reduced carbonate production, and platform drowning. This event, contrasting with the prevailing greenhouse conditions of the Mesozoic, is attributed to enhanced silicate weathering of the Paraná-Etendeka large igneous province basalts, leading to carbon sequestration, ocean fertilization, and localized anoxia without widespread warming from CO₂ emissions. Paleoenvironmentally, the stage saw shifts from oligotrophic to mesotrophic marine communities, potential polar ice formation, and arid conditions in some low-latitude areas, influencing biodiversity and sedimentary patterns worldwide.

Stratigraphy

Definition and Boundaries

The Valanginian Stage is a chronostratigraphic unit of the Lower Series, spanning approximately 4.45 million years from 137.05 ± 0.2 Ma at its base to 132.6 ± 0.6 Ma at its top, according to the International Chronostratigraphic Chart. This stage represents a key interval in the , characterized by significant evolutionary developments in marine biota and depositional environments primarily recorded in hemipelagic successions. The name "Valanginian" originates from the town of Valangin in the of , where characteristic strata were first studied; it was formally proposed by the Swiss geologist Édouard Desor in 1853 to designate the lowermost division of the Neocomian (now Lower ). Desor's designation was based on lithological and evidence from exposures in the Swiss Jura, establishing it as a foundational unit in . The base of the Valanginian is defined by the first occurrence of the ammonite species Thurmanniceras pertransiens (formerly placed in the genus Thurmanniceras), marking the Berriasian-Valanginian boundary. This Global Stratotype Section and Point (GSSP) is located at the base of limestone bed VGL-B136 (19.23 m above the section base) in the Vergol section near Montbrun-les-Bains, Department, southeastern (44°12′11″N, 5°25′03″E). The GSSP was ratified by the (IUGS) in December 2024, following detailed correlation using ammonite biostratigraphy, (base of Chron M18r), and astrochronology. Lithologically, the boundary is characterized by rhythmic alternations of limestones and shales typical of the Vocontian Basin hemipelagic deposits, reflecting Milankovitch-scale cyclicity in sedimentation. The top of the Valanginian, corresponding to the Valanginian-Hauterivian boundary, is defined by the first occurrence of the ammonite Acanthodiscus (exemplified by A. rebouli), coinciding with the base of magnetic subchron M5n.2n. The GSSP for this boundary is situated at the base of bed 189 in the La Charce section, Vocontian Basin, Department, southeastern (44°27′00″N, 5°26′37″E), ratified by the IUGS in December 2019. At this boundary, the transitions to marly limestones, indicative of continued hemipelagic conditions with subtle shifts in carbonate content and clay input.

Subdivision and Biostratigraphy

The Valanginian Stage is divided into two substages: the Lower Valanginian, spanning from the base of the stage—defined by the first occurrence of the ammonite Thurmanniceras pertransiens—to the base of the Saynoceras verrucosum Zone, and the Upper Valanginian, extending from the S. verrucosum Zone to the top of the stage. This division reflects major faunal turnovers in ammonite assemblages and aligns with lithological shifts observed in Tethyan sections. In the Tethyan domain, relies primarily on ammonites, with encompassing five key biozones: the basal Thurmanniceras pertransiens (Lower Valanginian), followed by the Busnardoites campylotoxus , the Saynoceras verrucosum (marking the Lower-Upper substage boundary), the Himantoceras trigo , and the uppermost Acanthodiscus . These zones are calibrated through detailed section studies in reference areas like southeastern and the Betic of , where index fossils provide high-resolution temporal control. Correlation across sections and basins integrates multiple proxies beyond ammonites. nannofossils offer auxiliary markers, such as the first occurrence of Tubodiscus verenae near the base of the T. pertransiens Zone and Calcicalathina oblongata within it, while benthic provide limited but supportive resolution in shallow-water settings. further refines global ties, with the Valanginian encompassing chrons from M18n at the base to M0r near the top, as documented in hemipelagic sequences like those at Cehegín, . Regional discrepancies in arise between the Tethyan and Boreal realms due to provincial faunas. The Tethyan scheme, centered on Mediterranean ammonites, contrasts with Boreal zonations that emphasize endemic genera such as Platylenticeras and Paratollia, requiring cross-realm calibrations via more cosmopolitan nannofossils like Micrantholithus speetonensis.

Paleogeography and Climate

Tectonic Setting and Paleogeography

During the Valanginian stage of the Early Cretaceous (approximately 137.0–132.6 Ma), the breakup of the supercontinent Pangea was well advanced, marking the continued separation of Laurasia in the north from Gondwana in the south following the initial rifting of the Central Atlantic in the Early Jurassic. At this time, the global plate configuration featured a dispersed arrangement of continents, with North America, Eurasia, Africa, South America, India, Australia, and Antarctica as distinct landmasses, though still connected in a loose Gondwanan framework. Paleomagnetic reconstructions indicate that the equator traversed northern South America, central Africa, and southern Asia, positioning the Tethys Ocean astride the equator and influencing latitudinal distributions of land and sea. Key rifting events characterized the Valanginian tectonic regime, including the propagation of extension in the South Atlantic between and , where syn-rift basins developed as part of the ongoing fragmentation. This rifting, initiated in the , shifted to a northwest-southeast orientation during the Valanginian-Hauterivian interval (140–130 Ma), leading to the formation of lacustrine and fluvial systems in rift valleys. In the realm, rifting between and the Australia-Antarctica block, which began in the , progressed into the , with significant crustal extension and the onset of along the southwest Australian margin. Meanwhile, the Central Atlantic, already open since the (around 177 Ma), experienced continued that contributed to the northward drift of relative to . Regionally, the formed a prominent, relatively narrow seaway separating the northern Laurasian landmasses from the southern Gondwanan continents, bordered by zones along its margins. Elevated global sea levels during this period resulted in widespread epicontinental seas inundating large portions of the continents, including shallow marine environments across , the western interior of , and , which facilitated sediment deposition in these intracratonic basins. These reconstructions, based on data such as chron M11 (approximately 136 Ma), highlight initial paths consistent with the ongoing dispersal of Pangea's remnants.

Climate and Sea-Level Changes

The Valanginian stage was marked by warm conditions, with atmospheric CO₂ levels estimated at 940–1480 based on carbon analyses of terrestrial . Global mean surface temperatures were approximately 5–10°C higher than modern values, reflecting the influence of elevated greenhouse gases and reduced polar volumes. Mid-latitude sea surface temperatures averaged around 24°C, while equatorial regions exhibited surface waters of 30–40°C, as inferred from stable oxygen data and paleotemperature proxies. These conditions supported a generally ice-free world, with no evidence for widespread glaciation except during transient perturbations. Eustatic sea-level dynamics during the Valanginian were driven primarily by thermal expansion of and minimal continental ice storage, contributing to overall highstands relative to present-day levels. Long-term sea level fluctuated between approximately 75 m and 170 m above present-day mean , with a notable trough in the mid-Valanginian followed by rising trends. A major occurred in the upper Valanginian, corresponding to the Va3 event, which led to widespread flooding of platforms and enhanced inundation of continental margins. These changes were superimposed on tectonic influences, such as rifting in the proto-Atlantic, but were predominantly climatically controlled. Ocean circulation patterns were shaped by the restricted configuration of the , which limited deep-water exchange and promoted stratified conditions in marginal basins. This restriction facilitated the development of anoxic environments, evidenced by the deposition of organic-rich black shales along the and margins, particularly in the North Atlantic and adjacent areas. Such sediments indicate episodic oxygen depletion in bottom waters, linked to reduced ventilation and enhanced preservation of organic matter. Paleotemperature reconstructions rely heavily on oxygen isotope ratios (δ¹⁸O) from belemnite , which reveal a trend of equatorial warming through the early Valanginian, with δ¹⁸O values indicating sea surface temperatures increasing by 1–2°C before later fluctuations. These proxies, combined with /Ca ratios, confirm the absence of significant polar ice buildup under baseline conditions, supporting a dynamic but predominantly warm regime. Belemnite data from Tethyan sections further highlight latitudinal gradients, with warmer low-latitude signals contrasting cooler high-latitude trends.

Paleobiology

Marine Fauna

The marine fauna of the Valanginian stage exhibited significant , particularly in the Tethyan realm, where shallow shelf environments supported a range of and vertebrates adapted to varying oceanic conditions. Ammonites were among the most prominent , serving as key index fossils for across Mediterranean and Tethyan basins. Dominant genera included Thurmanniceras, which defined the lower Valanginian Thurmanniceras pertransiens through species like T. pertransiens, and Olcostephanus, with species such as O. drumensis and O. guebhardi marking subzonal transitions in marl-limestone sequences. These s, often preserved in hemipelagic settings, reflect a high degree of and faunal turnover, with boreal influences appearing in northern margins. Belemnites, another major group, were widespread predators in outer shelf and hemipelagic environments, exemplified by Duvalia species like D. emericii and D. lata, which formed assemblages with Hibolithes in siliciclastic-influenced shallow seas of the western Tethys and . Diverse gastropods and non-rudist bivalves inhabited shallow deposits, contributing to benthic communities in mixed carbonate-siliciclastic platforms. Rudist bivalves began to emerge as structure-formers in Tethyan platforms during the Valanginian, marking the initial diversification of these heterodonts in tropical shelves, though they were not yet dominant. Early records from the western Tethys include caprinid-like forms in shallow, high-energy environments, often associated with microbial and algal mats. Corals persisted in patch reefs and bioclastic calcarenites, with 51 species across 29 genera documented in the South Iberian Margin, including holdovers like Stylina and new elements such as Floriastrea iberica. Larger benthic , such as Pseudocyclammina and Everticyclammina, co-occurred with corals and dasycladalean algae like Clypeina jurassica in these oligotrophic to mesotrophic settings. Among vertebrates, early teleost fishes began their radiation, with otolith-based records from central Poland indicating a gradual diversification starting before the Valanginian, including clupeomorphs and other basal forms in nearshore deposits. Pycnodontiform fishes, characterized by specialized crushing dentition, were diverse in southern high-latitude basins, as seen in new taxa like Gyrodus huiliches and Tranawuen agrioensis from the Neuquén Basin of Argentina, adapted to durophagous feeding on invertebrates in shallow marine habitats. Sharks and rays occupied open-ocean niches, though specific Valanginian records are sparse. Marine reptiles included ichthyosaurs, with ophthalmosaurid remains like a complete rostrum from southeastern France representing the first definite Valanginian record, indicating persistence of post-Jurassic lineages in European epicontinental seas. Plesiosaurs, particularly large pliosaurids of the Brachaucheninae subfamily, acted as apex predators in proto-Caribbean shallow waters, as evidenced by cervical vertebrae from Colombia suggesting body lengths exceeding 10 meters. Tethyan reefs displayed high , with coral-rudist associations signaling the gradual transition toward rudist-dominated ecosystems that would characterize later shelves, driven by increasing nutrient flux and platform drowning events.

Terrestrial Fauna and Flora

The terrestrial ecosystems of the Valanginian stage were characterized by a gymnosperm-dominated , with , cycads, ginkgoaleans, and forming the primary components, alongside diverse and other pteridophytes. In and , palynological assemblages reveal abundant pollen and spores, indicating a where gymnosperms outnumbered other groups. The earliest definitive angiosperm fossils, including inaperturate pollen grains similar to those of modern , appear in the late Valanginian from localities in and , marking the initial diversification of flowering plants in mid-paleolatitude regions of and northern . These early angiosperms were likely small, herbaceous, and ruderal in habit, coexisting with the established gymnosperm without yet dominating ecosystems. Vegetation structure varied by latitude and environment, with conifer-dominated forests prevalent in higher latitudes and mid-latitude floodplains featuring fern understories amid open woodlands of cycads and ginkgoaleans. In southern , such as the Basin, palynomorphs show low-diversity assemblages with dominant fern spores like Cyathidites and Gleicheniidites, suggesting humid, fern-rich lowlands interspersed with stands adapted to seasonal . Higher-latitude sites in and indicate denser forests, with ginkgoalean leaves and cycad-like fronds contributing to a stratified canopy over fern-dominated ground cover. This gymnosperm-centric vegetation supported a range of herbivorous terrestrial vertebrates, reflecting a stable but transitional floral regime before the angiosperm radiation. Dinosaur assemblages in the Valanginian were diverse, particularly in and southern , with theropod, ornithischian, and sauropodomorph remains and tracks documenting active continental ecosystems. In , the Broome Sandstone preserves extensive theropod tracks, including those assigned to the ichnogenus Walmadanyichnus, attributed to medium- to large-bodied carnivorous dinosaurs navigating coastal floodplains. Ornithischians, including thyreophorans such as nodosaurids, are represented by skeletal material from Spain's Valanginian deposits, indicating armored herbivores browsing in forested or riparian habitats. Early sauropodomorphs, evidenced by trackways in the same Australian formations, suggest the presence of long-necked herbivores that were becoming less dominant compared to later forms. Beyond dinosaurs, terrestrial faunas included small mammals, pterosaurs, reptiles, insects, and amphibians, with Gondwanan assemblages showing particular diversity among non-dinosaurian reptiles. Small therian mammals, such as early tribosphenidans, are inferred from sparse dental and postcranial fossils in southern continents, occupying insectivorous or omnivorous niches in understory environments. Pterosaurs, including early pterodactyloids, contributed to aerial components of these ecosystems, with post-Valanginian records in indicating continuity from forms into Gondwanan skies. In , diverse reptiles such as crocodyliforms and squamates thrived in fluvial settings, as seen in localities with lizard skeletons from Berriasian-Valanginian beds. , including early beetles and flies preserved in or compressions, and amphibians like albanerpetontids, rounded out the , supporting a complex beneath the canopy.

Significant Events

Weissert Event

The Weissert Event, occurring approximately 134.56 ± 0.19 million years ago, represents a significant climatic perturbation during the mid-Valanginian stage, spanning from the late Lower Valanginian to the early Upper Valanginian and lasting about 1 million years. Recent estimates suggest a duration of ~2.08 million years (as of 2025). This event interrupted the prevailing Early Cretaceous greenhouse climate with a pronounced cooling episode, evidenced by positive shifts in oxygen isotope ratios (δ¹⁸O) from belemnite and bulk carbonate records across multiple paleolatitudes. Indicators of southern high-latitude glaciation, including dropstones, tillites, and glendonites in sedimentary sequences from regions such as southern Australia and the Antarctic Peninsula, further support the development of transient ice sheets during this interval. Globally, the Weissert Event led to a reduction in sea surface temperatures by approximately 3°C (±1.7°C), based on clumped thermometry and oxygen analyses from low- to mid-latitude sites. This cooling facilitated the expansion of oxygen minimum zones in epicontinental seas and ocean basins, promoting the deposition of organic-rich black shales in restricted basins like the Vocontian Trough and the Neuquén Basin. Although set against a backdrop of overall warm conditions, the event's thermal decline contributed to eustatic sea-level fluctuations, influencing sedimentary patterns in both hemipelagic and platform environments. Biologically, the Weissert Event exerted stress on marine ecosystems without triggering a major mass extinction. Among calcareous nannoplankton, it caused a pronounced decline in nannoconids—key reef-forming and pelagic —linked to enhanced surface-water and reduced efficiency during cooling. Planktonic experienced minor species turnovers and localized extinctions, particularly in low-oxygen niches, while benthic communities showed resilience but with shifts toward opportunists. platform systems, including reefs, faced drowning episodes and reduced growth rates due to cooler waters and nutrient influx, as recorded in Tethyan and peri-Gondwanan margins, though recovery followed within a few million years.

Volcanic and Isotopic Anomalies

The Valanginian stage is marked by a prominent positive carbon isotope excursion (CIE) in carbonates, with δ¹³C values shifting upward by approximately 2‰, reflecting enhanced burial of carbon and perturbations in the global . This excursion, often termed the Weissert , initiated near the early-late Valanginian boundary (around 135 Ma) and persisted into the late Valanginian, as recorded in sections from the Vocontian Basin and Polish Basin. The CIE amplitude reached up to 2.5‰ in some Tethyan records, indicating a drawdown of atmospheric CO₂ through increased productivity and . Volcanic activity during the Valanginian is primarily associated with the onset of the , whose main eruptive phase occurred at approximately 134.6 ± 0.6 Ma, aligning closely with the CIE onset. This emplacement released substantial volumes of CO₂ and compounds, with mercury () enrichments in sediments serving as a for intense volcanic ; peak Hg concentrations reached 70 ppb in French sections and 70 ppb in Polish sites, coinciding with the Campylotoxus Zone. These anomalies suggest episodic magmatic pulses that influenced ocean chemistry and the hydrological cycle, contributing to the observed geochemical perturbations. Strontium isotope records (⁸⁷Sr/⁸⁶Sr) during the Valanginian exhibit a general increasing trend from 0.70729 at the base to higher values toward the Hauterivian, but feature a notable plateau and small excursion to lower ratios (around 0.7073) in the late Valanginian. This deviation is interpreted as evidence of enhanced continental weathering, possibly driven by humid climatic conditions that intensified silicate breakdown and nutrient flux to oceans. Such weathering signals may connect to broader environmental instability, including potential precursors to the Faraoni oceanic anoxic event in the late Hauterivian (circa 131 Ma), where organic-rich deposits indicate transient oxygen depletion in Tethyan basins. Causal mechanisms link these anomalies to , where initial CO₂ emissions promoted greenhouse warming and , while subsequent SO₂ injections and organic carbon burial facilitated CO₂ drawdown, culminating in transient cooling. This sequence of volcanic forcing and biogeochemical feedbacks underscores the Valanginian's role in climate dynamics.