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Early Devonian

The Early Devonian epoch, the initial subdivision of the Period within the Era, extended from approximately 419.6 to 393.5 million years ago and is divided into three stages: the Lochkovian (419.6–413.0 Ma), Pragian (413.0–410.6 Ma), and Emsian (410.6–393.5 Ma). This epoch represented a pivotal transition in Earth's history, characterized by the stabilization of continental configurations into the supercontinents of and Euramerica, with much of the latter positioned near the and covered by warm, shallow epicontinental seas that facilitated widespread deposition and the initial development of systems built by tabulate and rugose corals. Geologically, the Early Devonian featured relatively high global sea levels, promoting expansive marine environments and limited terrestrial exposure, though tectonic activity along continental margins, such as the early phases of the in eastern , began influencing sedimentation patterns with increased siliciclastic inputs in nearshore settings. Paleontologically, marine ecosystems were dominated by diverse brachiopods (including spiriferids), , and trilobites, while vertebrates underwent rapid : jawless fishes (agnathans) persisted as bottom-dwellers, but forms like placoderms and early sarcopterygians (lobe-finned fishes, precursors to tetrapods) diversified, marking the onset of the "Age of Fishes." In terrestrial realms, small vascular plants such as zosterophylls and early lycophytes, reaching up to 1 meter in height without true roots or leaves, began colonizing coastal areas, contributing to the formation of primitive soils through organic decay, alongside the appearance of wingless arthropods like mites and the earliest . The climate during the Early Devonian was predominantly warm and equable, consistent with a state, with tropical conditions supporting growth and no evidence of widespread glaciation, though atmospheric CO₂ levels began a gradual decline toward the epoch's end. These conditions fostered biotic innovations, including the first ammonoids in settings and enhanced nutrient cycling from emerging land vegetation, setting the stage for more complex ecosystems in the subsequent Middle .

Definition and nomenclature

Subdivisions

The Early , also known as the Lower Devonian series, is subdivided into three chronostratigraphic stages: the Lochkovian at the base, followed by the Pragian, and then the Emsian at the top. These stages provide the temporal framework for the period, spanning approximately 26 million years in total, and are defined primarily through using and , integrated with . Numerical ages are based on the International Chronostratigraphic Chart v2024/12. The Lochkovian stage, the oldest subdivision of the Early Devonian, extends from 419.62 ± 1.36 Ma to 413.02 Ma, lasting about 6.6 million years. Its is marked by the datum (FAD) of the Uncinatograptus uniformis in the Uncinatograptus uniformis , which serves as a key biostratigraphic marker for the Silurian-Devonian boundary and the onset of the stage. biozonation within the Lochkovian includes such as the Icriodus hesperius at the , transitioning upward through like I. woschmidti and Ancyrognathus triangularis. These help correlate the stage across global sections, with its global stratotype section and point (GSSP) located at Klonk, . The Pragian stage follows the Lochkovian and spans from 413.02 Ma to 410.62 ± 1.91 Ma, with a duration of roughly 2.4 million years. It is characterized by the FAD of the conodont Eognathodus sulcatus sulcatus at its base, defining the E. sulcatus as the primary marker. Upper parts of the stage feature zones such as the Icriodus steinhornensis Zone. The Pragian GSSP is situated at the Velká Chuchle Quarry, , . The Emsian stage caps the Early Devonian, ranging from 410.62 ± 1.95 Ma to 393.47 ± 0.99 Ma and lasting approximately 17.2 million years. Its lower boundary is defined by the FAD of the Polygnathus kitabicus in the P. kitabicus . Key biozones include those dominated by Nowakia species, while conodont zonation progresses through P. pireneae, P. szekelyensis, and P. nothsi zones upward. The stage's GSSP is at Zinzil'ban Gorge, .

Boundaries

The lower boundary of the Early , which corresponds to the base of the Lochkovian Stage and the System overall, is defined by the first appearance datum () of the Uncinatograptus uniformis (formerly classified as Monograptus uniformis). This marker occurs in Bed 20 of the Global Stratotype Section and Point (GSSP) at the Klonk section, located approximately 35 km southwest of near Suchomasty in the . The GSSP was ratified in 1972 by the (ICS), making it the first international stratotype established under modern global standards for . The upper boundary of the Early , delineating the transition to the Eifelian Stage and the base of the Middle Series, is defined by the of the Polygnathus costatus partitus. This biostratigraphic event is pinpointed at 21.25 m above the base of the exposed section in the GSSP at the Wetteldorf Richtschnitt site, within the Upper Heisdorf Formation near Schönecken-Wetteldorf in the Hills of . Ratification occurred in 1985, further solidifying the framework for stage boundaries through precise fossil-based correlations. The historical nomenclature for these boundaries evolved significantly from 19th-century regional classifications, initially proposed by geologists like based on lithostratigraphic units such as the in and the Welsh borderlands, to the standardized biostratigraphic approach adopted by the . This shift, formalized through international committees starting in the 1960s and culminating in the 1972 ratification at the 24th International Geological Congress in , prioritized globally correlatable events like and appearances over variable local rock descriptions. By the 1980s, this evolution ensured consistent worldwide application, integrating diverse fossil groups for accurate temporal delimitation.

Stratigraphy

Global stratotype sections

The Global Stratotype Section and Point (GSSP) for the base of the Early , which coincides with the - boundary and the onset of the Lochkovian Stage, is located at Klonk Hill near Suchomasty in the Synform, (coordinates: 49.8550°N, 13.7920°E). This site was ratified by the () in 1972 as the first GSSP in geological history, serving as the international reference for correlating the lower boundary of the worldwide. The section exposes a continuous sequence of uppermost (Kopanina Formation) and lowermost () strata, consisting primarily of shales, marly limestones, and shales with interbedded bioclastic limestones, reaching a thickness of about 5 meters across the boundary interval. The boundary is precisely defined at the base of Bed 20 by the first appearance datum (FAD) of the Uncinatograptus uniformis, accompanied by other index fossils such as the Icriodus woschmidti and the Howellella crispa. This marker enables high-resolution correlation, as U. uniformis appears synchronously in hemipelagic deposits globally, reflecting a rapid post-extinction recovery following the Late Lau Event. The GSSP for the upper boundary of the Early Devonian, defining the base of the Middle Devonian Eifelian Stage, is situated in the Wetteldorf Richtschnitt section near Schönecken in the Eifel Mountains, , (coordinates: 50.1496°N, 6.4716°E). Ratified by the in 1985, this site provides the primary reference for the Emsian-Eifelian , facilitating global correlation of the latest Early Devonian rocks. The exposed section, approximately 60 meters thick, comprises a hemipelagic sequence of dark, micritic limestones and shales of the Klerf Formation (upper Emsian) transitioning into the Fischen Formation (lower Eifelian), with rhythmic alternations reflecting Milankovitch cyclicity. The is placed 21.25 meters above the base of the exposed section, at the base of sample station WP30 (Bed 9/5 equivalent), marked by the FAD of the conodont Polygnathus costatus partitus, which occurs without significant facies change or hiatus. Supporting includes the last occurrences of Emsian index conodonts like Icriodus clavatus and the onset of Eifelian trilobites and brachiopods, ensuring precise identification in carbonate-dominated successions. Global correlation of Early Devonian strata relies on integrated using for the basal Lochkovian boundary, for stage-level subdivisions including the Emsian-Eifelian , and chitinozoans for enhanced resolution in deeper-water or organic-rich deposits. In Europe, zones (e.g., Uncinatograptus uniformis Zone) correlate the Klonk section with hemipelagic shales in the and Synform, while biofacies (e.g., Polygnathus platforms) link the Wetteldorf GSSP to shallow-marine carbonates in the Mountains and . Across , these markers align sequences (e.g., Group) with European standards via like Icriodus and chitinozoans such as Thallochitina , resolving provincial variations in the Basin and . In , particularly blocks, conodont-chitinozoan assemblages (e.g., Eognathodus and Pterochitina zones) correlate Platform sections with the GSSPs, bridging Gondwanan and Laurussian faunas through shared index taxa. The (ICS), via its Subcommission on Devonian Stratigraphy (), oversees the ratification and maintenance of these GSSPs, ensuring their utility in the International Chronostratigraphic Chart. Ratifications followed extensive international and fieldwork, with Klonk established as a for stratotypes and Wetteldorf selected after evaluating multiple candidates for its continuous pelagic . Ongoing updates, such as numerical age refinements in the 2023 chart version (e.g., Early Devonian base at 419.6 ± 0.9 Ma and top at 393.3 ± 1.1 Ma based on U-Pb dating), incorporate new geochronological data to enhance global synchronization. These revisions reflect ICS efforts to integrate with radioisotopic ages, maintaining the GSSPs' role in precise inter-regional correlations.

Lithostratigraphy

Early Devonian strata worldwide exhibit a predominance of shallow marine carbonates and marginal to continental siliciclastics, reflecting diverse depositional environments from reefs and shelves to deltas and fluvial systems. In the Basin of eastern , the Helderberg Group exemplifies shallow marine carbonate deposition, comprising interbedded limestones, dolomites, and minor shales formed in subtidal to peritidal settings with evidence of periodic exposure. These rocks, up to several hundred meters thick, record transgressive-regressive cycles in a carbonate environment. In contrast, siliciclastic-dominated sequences characterize much of northern Euramerica, particularly the of the Anglo-Welsh Basin and Orcadian Basin in . This informal lithostratigraphic unit consists primarily of red-colored sandstones, conglomerates, and mudstones deposited in alluvial fans, rivers, lakes, and coastal plains, with thicknesses exceeding 3,000 meters in places and featuring fining-upward cycles indicative of fluvial and . The Lower Old Red Sandstone subgroup, spanning the Early Devonian, includes cross-bedded arenites and siltstones that document terrestrial to paralic transitions. Key formations highlight specific within these broader patterns. During the Pragian stage, the Siegenian sandstones in the Rhenohercynian Basin of represent deltaic and shallow environments, with medium- to coarse-grained sandstones interbedded with mudstones and exhibiting influences, bioturbation, and debris in a land-sea transition zone. Spanning the late Pragian to early Emsian, the Ditton Group in the Anglo-Welsh Basin comprises stacked fining-upward sequences of sandstones, siltstones, and mudstones deposited in and settings, with calcretes and paleosols indicating periodic aridity. These units correlate broadly to the Early Devonian stages outlined in regional . Regional lithological variations distinguish Euramerican sequences from those in . Euramerican deposits emphasize carbonate platforms and extensive continental , whereas Gondwanan strata, such as in the Amazonas Basin of northern , feature marine to marginal siliciclastics including sandstones, shales, and minor conglomerates in subtidal shelf environments, with localized evaporites in restricted arid basins reflecting hypersaline conditions. In northwestern , including , Early Devonian rocks of the Floresta Formation consist of fossiliferous sandstones and shales indicative of open marine shelves.

Paleogeography

Continental configurations

During the Early Devonian, the major continental landmasses underwent significant northward drift, with and converging to form the core of the supercontinent Euramerica (also known as Laurussia). , encompassing much of present-day and , was positioned in tropical to subtropical latitudes, oriented roughly similarly to its modern configuration but rotated slightly counterclockwise. , including much of , had already collided with during the , and both cratons continued drifting equatorward from higher latitudes, facilitating the development of extensive shallow epicontinental seas across Euramerica. This assembly is supported by paleomagnetic data indicating relative positions that promoted warm, humid conditions conducive to early terrestrial ecosystems. Gondwana, the vast southern comprising , , , , and , was centered over the , occupying high southern latitudes throughout the Early Devonian. This polar positioning contributed to cooler climatic conditions in its southern sectors. The supercontinent's stable configuration, assembled by the late , experienced minimal internal deformation during this interval, though its drift set the stage for later tectonic interactions. Avalonia, a peri-Gondwanan terrane including parts of , , and Newfoundland, had sutured to the southern margin of during the Late Silurian (ca. 423–419 Ma), prior to the Early Devonian, completing the closure of the Tornquist Sea following its earlier separation from in the . This suturing is evidenced by paleomagnetic poles aligning Avalonia with Baltica's latitude and the onset of shared sedimentary and magmatic signatures across the joined margin. Concurrently, the early stages of closure commenced as began its northward approach toward Euramerica, narrowing the ocean basin and initiating along its northern margins, though full closure would not occur until the late . Paleogeographic reconstructions for key Early Devonian intervals, such as the Pragian stage at approximately 410 Ma, are primarily based on integrated paleomagnetic paths, coupled with stratigraphic and faunal correlations. These models depict Euramerica straddling the equator, with fully integrated into its eastern flank, while dominated the southern high latitudes, separated by the widening Paleo-Tethys to the east and the proto-Atlantic to the west. Such reconstructions highlight the dynamic interplay of driving global paleoenvironmental patterns.

Ocean basins

During the Early Devonian, the global ocean system was dominated by the vast Ocean, which encircled the emerging supercontinent and featured simple circulation patterns characterized by subtropical gyres in both hemispheres, separated by an undulating . The , situated between the northern continents of Euramerica (Laurussia) and the southern supercontinent, began widening as a result of the rifting and northward drift of Cimmerian terranes from Gondwana's northern margin, marking the transition from the Proto-Tethys to the more expansive Paleo-Tethys seaway. This expansion facilitated increased connectivity between equatorial and higher-latitude waters, influencing early marine faunal dispersals. In contrast, the , positioned between and Euramerica to the south of the Paleo-Tethys, underwent significant narrowing due to the initiation of along its margins, with oblique subduction of thinned Gondwanan crust commencing around the Early Devonian. This contractionary phase reduced the Rheic's width, setting the stage for its eventual closure by the Late Devonian, and altered regional circulation by compressing equatorial currents between the approaching landmasses. Remnants of the earlier , closed by the Silurian collision of and , persisted as narrow proto-Atlantic basins or suture-related seaways, such as trapped corridors between and other terranes, contributing to localized circulation patterns that funneled waters from into emerging inter-continental gulfs. These features, influenced by the fixed continental configurations of the time, supported sluggish, wind-driven flows that connected residual Iapetan waters to the broader Panthalassan system. Evidence for active subduction zones in these basins comes from Early Devonian ophiolites and associated volcanic , particularly in the Variscan and Uralian regions, where suprasubduction zone settings are indicated by the geochemical signatures of mafic-ultramafic complexes formed in forearc or backarc environments. For instance, ophiolites in the southern Urals and northwest exhibit compositions consistent with intra-oceanic arc development within the contracting , highlighting the role of in driving oceanic evolution.

Climate and environment

Temperature and atmospheric conditions

The Early Devonian climate was characterized by a predominantly warm and humid regime, with equatorial regions of the Euramerica experiencing tropical conditions conducive to extensive shallow marine environments and reef development. Global mean annual surface temperatures are estimated at 14.8–15.7 °C under atmospheric CO₂ levels around 500 ppm, supporting widespread warm-water across low-latitude settings. In contrast, higher-latitude portions of , positioned in the , supported cooler conditions, with modeling indicating partial glaciation possible in polar regions during periods of lower greenhouse forcing. Atmospheric composition featured elevated CO₂ concentrations of 525–715 (approximately 1.9–2.6 times pre-industrial levels), as reconstructed from stomatal density and pore size in lycophytes using mechanistic leaf-gas exchange models, alongside carbon (Δ¹³C) in phytane from marine phytoplankton and leaf tissues. Oxygen levels were rising during this interval, reaching or exceeding 15–17% (about 0.7 present atmospheric levels), driven by enhanced organic carbon burial from early vascular plants, as evidenced by abundance and biogeochemical modeling incorporating isotopes and iron speciation. These conditions reflect a transition from anoxia toward more oxygenated atmospheres and oceans by the Early-Middle boundary. Continental interiors, particularly in Euramerica's basins and South China's Guijiatun Formation, exhibit red bed sediments and calcareous paleosols (e.g., Calcisols) indicative of semi-arid landscapes with seasonal wet-dry cycles consistent with monsoonal precipitation regimes. These features, including pedogenic nodules and Vertisol-like profiles, suggest well-drained floodplains subject to periodic intense rainfall followed by prolonged aridity, fostering early colonization in dryland settings.

Sea level changes

The Early Devonian period featured prominent transgressive-regressive (T-R) cycles, reflecting global fluctuations that influenced sedimentary deposition across multiple paleocontinents. A notable lowstand occurred during the early Lochkovian stage, continuing a broader decline initiated in the Late Silurian, with relative sea levels reaching eustatic minima that exposed large portions of continental shelves. This lowstand is documented in sequence stratigraphic records from regions such as the Appalachian Basin and the Nevada Antelope Range, where unconformities and terrestrial deposits indicate widespread subaerial exposure. The transition from this lowstand culminated in a significant during the late Lochkovian to Pragian stages, characterized by rapid marine flooding of cratonic interiors and pericratonic basins. This Pragian event led to the inundation of vast areas, including parts of Laurussia and margins, promoting the development of shallow-marine platforms and mixed siliciclastic- systems. Global correlation of these cycles, based on and lithofacies shifts, confirms the eustatic nature of the rise, with onlap patterns extending onto stable cratons. A key example of from this is observed in the Group of eastern , where the Pragian marine incursion deposited a series of third-order cycles comprising limestones and over an approximately 8–10 million year interval. These sequences record initial lowstand deposits overlain by transgressive systems tracts, with maximum flooding surfaces marked by diverse benthic faunas indicative of deepened shelf environments. The exemplifies how eustatic rises, modulated by regional thermal subsidence, facilitated widespread habitat expansion in shallow seas. Eustatic variations during these cycles were primarily driven by long-term thermal subsidence of expanding ocean basins, alongside shorter-term tectonic and climatic influences, with event amplitudes ranging from medium (25–75 m) to (>75 m) in magnitude. These fluctuations, averaging durations of about 1–2 million years for third-order cycles, underscore the dynamic interplay between global tectonic processes and dynamics in shaping Early Devonian paleoenvironments.

Tectonic events

Orogenic activities

The Early Devonian marked the initiation of the , a major compressional event driven by the oblique collision between the microplate and the Laurentian margin, beginning in the Lochkovian stage (approximately 419–411 Ma). This collision produced widespread folding and ing in the region, with early deformation manifesting as lithospheric flexure and basin subsidence patterns recorded in the Helderberg Group of , where unconformities and siliciclastic influx indicate tectonic loading from advancing thrust sheets. The orogeny contributed to the suturing of to , forming part of the broader assembly of Euramerica, with timing varying regionally from the Lochkovian in eastern areas to the early Emsian elsewhere. In Euramerica, residual effects of the Silurian Caledonian orogeny continued into the Early Devonian, with minor transpressional deformation and erosion shaping northern margins around 410–400 Ma. This phase involved continued shortening along the Iapetus suture, leading to localized uplift and the deposition of Old Red Sandstone continental sediments derived from eroding Caledonide highlands. Minor precursors to the Variscan orogeny emerged in central Europe during the Early Devonian, associated with initial plate convergence along the Rheic Ocean margin, involving low-grade metamorphism and faulting in the Saxo-Thuringian zone around 410–400 Ma. These events represented early compressional tectonics prior to the main Carboniferous collisional phase, with evidence preserved in the Odenwald Crystalline Complex as pre-Variscan structures overprinted on Cadomian basement. Sediment provenance studies using detrital zircon U-Pb geochronology reveal that Early Devonian clastic deposits in the Appalachian foreland and adjacent basins were primarily sourced from uplifts generated by these orogenic activities, with age clusters peaking at 450–420 Ma (Caledonide sources) and emerging 410–400 Ma populations (early Acadian arcs). For instance, in the Maine Appalachians, syncollisional strata of the Tarratine Formation contain zircons tracing material from proximal Caledonide hinterlands and newly exhumed Acadian fold-thrust belts, indicating rapid and basinward during Pragian-Emsian deformation. Similar patterns in central basins link detrital signatures to Variscan precursor uplifts, underscoring the role of orogenic in fueling continental .

Rifting and subduction

During the Early Devonian, in the Paleo-Tethys region involved back-arc rifting associated with the initial opening of the ocean basin along the northern margin. This process detached Cimmerian terranes, leading to and the formation of a narrow realm between ~420 and 380 Ma. Convergent margin dynamics were prominent along the margins, where initiated the closure of this ocean basin. Northward beneath the southern margin of and southward beneath northwest produced systems, documented by subduction-related volcanic products in the Rhenohercynian Zone. These arcs formed as a result of Rheic slab consumption starting in the Early Devonian, contributing to the assembly of peri-Gondwanan terranes. Volcanism linked to these extensional and convergent processes included basaltic sequences in the Rhenohercynian Basin of , such as those in the Emsian stage of the , indicative of rift-related magmatism. In , ophiolite suites in the and regions, remnants of suprasubduction zone settings, record Early Devonian oceanic crust formation tied to Rheic margin dynamics. Paleomagnetic reconstructions indicate plate velocities of 2–5 cm/yr during this period, consistent with averages and supporting the rates of rifting and observed in global models.

Life

Marine invertebrates

During the Early Devonian, marine invertebrate faunas were dominated by brachiopods, which formed extensive populations in shallow shelf seas across paleocontinents like and . These bivalved organisms, particularly from the order Atrypida, exhibited high diversity and abundance, with genera such as Atrypa commonly preserved in deposits, reflecting their role as key suspension feeders in stable benthic habitats. Atrypid brachiopods, characterized by their spiraled brachial valves, proliferated in the Lochkovian and Pragian stages, adapting to normal marine salinities and contributing to the ecological foundation of early seafloors. Trilobites, though experiencing a post-Silurian decline in overall diversity, persisted as important elements of these communities, particularly in nearshore and shelf environments. Genera like Otarion, known from formations such as the Haragan and Bois d'Arc in , displayed robust exoskeletons suited to mobile scavenging or predation on soft substrates, with fossils indicating their presence in the Lochkovian to Emsian intervals. These arthropods often co-occurred with brachiopods, underscoring a mixed mobile-epifaunal assemblage typical of Early Devonian paleoenvironments. Tabulate and rugose corals emerged as significant reef-builders during this period, constructing small, patchy reefs and bioherms in warm, shallow waters rather than the expansive structures of later times. Tabulates, with their polygonal corallites and horizontal tabulae, formed colonial frameworks that supported associated , while solitary rugose corals like Syringaxon provided sites for these early biogenic structures. These reefs, often less than a few meters in relief, fostered localized hotspots in epeiric seas, enhancing complexity for co-occurring fauna. A pivotal evolutionary event was the origin of ammonoids from bactritoid ancestors, occurring in the Lochkovian stage around 419–411 million years ago, with transitional forms exhibiting loosely coiled shells and orthoconic traits inherited from their straight-shelled forebears. By the Emsian stage (approximately 407–393 million years ago), ammonoids diversified rapidly, including early goniatites such as those in the family Mimosphinctidae, which developed tighter coiling and complex septa, marking their adaptation to nektonic lifestyles in open settings. This radiation introduced more dynamic predators to Early Devonian oceans, influencing trophic interactions among invertebrates. Benthic shelf communities were particularly diverse, dominated by suspension-feeding guilds that included ostracods and , which colonized soft to firm substrates in oxygenated, low-energy environments. Ostracods, small bivalved crustaceans, formed dense populations in siliciclastic and sediments, with genera adapted to shallow shelves providing insights into microhabitat partitioning. Crinoids, as stalked echinoderms, contributed to these assemblages by anchoring to the seafloor and filter-feeding on , with their often concentrated in lag deposits indicating moderate current activity. Together, these groups exemplified the resilient, filter-dominated of Early Devonian continental margins, supporting broader food webs without vertebrate dominance at this stage.

Vertebrates and early tetrapods

The Early Devonian marked a pivotal transition in , characterized by the decline of jawless agnathans and the rapid of jawed gnathostomes. Jawless fishes, which had dominated and aquatic ecosystems, began to wane as environmental pressures and competition from more efficient feeders intensified, with their familial diversity showing no direct to the rise of gnathostomes but overall abundance diminishing through the period. Evidence from fossil assemblages, including lagerstätten such as the Miguasha site, illustrates this shift, where agnathans like thelodonts and osteostracans become increasingly rare amid the proliferation of armored and bony fishes. Placoderms, an extinct group of armored jawed fishes, underwent their primary during the Early , achieving a total diversity of over 335 genera across the Devonian in both marine and freshwater environments across all continents. This diversification, spanning from the Lochkovian to Emsian stages, featured shared traits like a bony head shield and thoracic armor, enabling adaptation to diverse niches from reefs to rivers. Arthrodires, a prominent placoderm order exemplified by predatory forms like Phyllolepis from late Lochkovian deposits in , featured robust mechanisms and paired fins, contributing to their ecological success as apex predators. Osteichthyes, the bony fishes ancestral to modern teleosts and , also radiated prominently in the Early Devonian, with stem-group taxa appearing in Pragian and freshwater settings. Early sarcopterygians, including osteolepiforms such as Porolepis from Pragian horizons, exhibited lobe-like fins and robust skulls suited to shallow-water habitats, marking initial steps toward morphology. These fishes, documented in sites like the Gogo Formation equivalents, coexisted with actinopterygians but emphasized the sarcopterygian lineage's role in bridging aquatic and terrestrial realms. By the late Emsian, the earliest tetrapod-like sarcopterygians emerged as precursors to later forms like Eusthenopteron, featuring flattened skulls, strengthened fin skeletons, and adaptations for marginal marine environments that foreshadowed limb . However, no confirmed body fossils or trackways are known from the Early Devonian; the earliest evidence of tetrapods appears in the early Middle Devonian (~390 Ma), including trackways from deposits, driven by rising oxygen levels and shallow-water conditions.

Flora and terrestrial ecosystems

The Early Devonian marked the initial colonization of land by vascular plants, with the first true tracheophytes appearing during the Pragian stage around 410 million years ago. These pioneering plants, belonging to the rhyniophytes and cooksonioids, were simple, leafless structures adapted to moist environments, featuring dichotomously branching axes and terminal sporangia for reproduction. Exemplary fossils include Rhynia gwynne-vaughanii and Cooksonia pertonii from the in , a preserving these plants in exquisite detail from approximately 407 million years ago. During this period, the Zosterophyllopsida underwent significant diversification, forming a paraphyletic grade of early vascular plants that contributed substantially to terrestrial floras. This group, characterized by leafless stems and laterally borne sporangia, radiated in the Lochkovian and peaked in diversity during the Pragian, before declining in the Emsian. Early lycopods, such as Drepanophycus and basal forms related to Baragwanathia, emerged as part of this diversification, representing precursors to modern clubmosses with features like exarch protosteles. Seed plants were entirely absent, as all Early Devonian vascular flora relied on spore-based reproduction. Terrestrial ecosystems began to develop around these , supported by the high of the Early Devonian that facilitated their . Arthropods, including millipedes as early herbivores and detritivores, interacted with the , as evidenced by coprolites from the Lochkovian of the Welsh Borderland containing fungal and nematophyte remains, indicating selective mycophagy around 419 million years ago. Fungal symbioses, resembling primitive mycorrhizae, associated with plant roots to enhance nutrient uptake from nutrient-poor substrates. These interactions, combined with plant-driven chemical weathering of , initiated by breaking down and promoting accumulation.

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