Rather than plants, it was
fungi, in particular
nematophytes such as Prototaxites, that dominated the early stages of this terrestrial biodiversification event. Nematophytes towered over even the largest land plants during the Silurian and Early Devonian, only being truly surpassed in size in the Early Carboniferous. The nutrient-distributing glomeromycotan mycorrhizal networks of nematophytes were very likely to have acted as facilitators for the expansion of plants into terrestrial environments, which followed the colonising fungi.[11] The first
fossils of
arbuscular mycorrhizae, a type of symbiosis between fungi and vascular plants, are known from the Early Devonian.[12]
Land plants probably evolved in the Ordovician.[13] The earliest
radiations of the first land plants, also known as
embryophytes, were
bryophytes, which began to transform terrestrial environments and the global climate in the Ordovician.[14][15][16]Baltica was a particularly important cradle for early land plant evolution, with it having a diverse flora by the
Darriwilian.[17] ∆199Hg and ∆200Hg excursions reveal that land plants had already spread across much of the Earth's land surface by the
Early Silurian.[18] The end of the
Homerian glaciation, a glacial phase of the
Early Palaeozoic Ice Age, and the corresponding period of global warming marked the first major diversification of plants that produced trilete spores. The later glaciation during the middle
Ludfordian, corresponding to the
Lau event, led to a major
marine regression, creating significant areas of new dry land habitat that were colonised by plants, along with cyanobacterial mats. These newly created terrestrial habitats helped facilitate the global expansion and
evolutionary radiation of
polysporangiophytes.[19] A warming climate during the subsequent
Pridoli epoch lent itself to further floral diversification.[20] During the
Wenlock epoch of the Silurian, the first
fossils of
vascular plants appear in the fossil record in the form of
sporophytes of
polysporangiophytes.[21] Lycophytes first appeared during the later
Ludlow epoch in the form of Baragwanathia,[22] which was an aquatic predecessor of fully terrestrialised lycophytes.[23]Palynological evidence points to Silurian terrestrial floras exhibiting little provincialism relative to present day floras that vary significantly by region, instead being broadly similar across the globe.[24] Plant diversification in the Silurian was aided by the presence of numerous small, rapidly changing
volcanic islands in the
Rheic Ocean that acted as natural laboratories accelerating evolutionary changes and enabling distinct, endemic floral lineages to arise.[25] Silurian plants rarely reached large sizes, with heights of 13 cm, achieved by Tichavekia grandis, being exceptionally large for the time.[26]
The Devonian witnessed the widespread greening of the Earth's surface,[27] with many modern vascular plant clades originating during this period.
Basal members of
Euphyllophytina, the
clade that includes
trimerophytes,
ferns, progymnosperms, and
seed plants, are known from
Early Devonian fossils.[28]Lycopsids experienced their first evolutionary radiation during the Devonian period.[13] Early Devonian plant communities were generally similar regardless of what landmass they inhabited,[29] although zosterophyllopsids displayed high levels of endemism.[30]
In the Middle Devonian, euphyllophytes continued to increase in diversity.[31] The first true forest environments featuring trees exceeding eight metres in height emerged by the Middle Devonian,[32] with the earliest known fossil forest dating to the
Eifelian.[33] The oldest known trees were members of the clade
Cladoxylopsida.[34] Devonian swamp forests were dominated by giant horsetails (
Equisetales), clubmosses, ancestral ferns (
pteridophytes), and large
lycophyte vascular plants such as
Lepidodendrales, referred to as scale trees for the appearance of scales on their
photosynthetic trunks. These lycophytes, which could grow up to 40 metres high, grew in great numbers around swamps along with tracheophytes.[9] Seed ferns and true leaf-bearing plants such as
progymnosperms also appeared at this time and became dominant in many habitats, particularly
archeopteridaleans, which were likely related to conifers.[35]Pseudosporochnaleans (morphologically similar to palms and tree ferns) likewise experienced a similar rise to dominance.[36] Archeopteridaleans had likely developed extensive root systems, making them resistant to drought, and meaning they had a more significant impact on Devonian soil environments than pseudosporochnaleans.[37]
The Late Devonian saw the most rapid land plant diversification of the Devonian, largely owing to the rapid radiation of pteridophytes and progymnosperms.[38] Cladoxylopsids continued to dominate forest ecosystems during the early Late Devonian.[34] During the latest Devonian, the first true spermatophytes appeared, evolving as a sister group to archaeopteridaleans or to progymnosperms as a whole.[39]
Most flora in Devonian coal swamps would have seemed alien in appearance when compared with modern flora, such as giant horsetails which could grow up to 30 m in height. Devonian ancestral plants of modern plants that may have been very similar in appearance are ferns (
Polypodiopsida), although many of them are thought to have been
epiphytes rather than grounded plants. True gymnosperms like ginkgos (
Ginkgophyta) and cycads (
Cycadophyta) would appear slightly after the Devonian in the
Carboniferous.[9]
Vascular plant lineages of sphenoids, fern,
progymnosperms, and seed plants evolved laminated leaves during the Devonian. Plants that possessed true leaves appeared during the Devonian, though they may have many independent origins with parallel trajectories of leaf morphologies. Morphological evidence to support this diversification theory appears in the
Late Devonian or
Early Carboniferous when compared with modern leaf morphologies. The
marginal meristem also evolved in a parallel fashion through a similar process of modified structures around this time period.[40] In a 1994 study by
Richard M Bateman and William A. Dimechele of the evolutionary history of
heterospory in the plant kingdom, researchers found evidence of 11 origins of
heterospory events that had occurred independently in the Devonian within
Zosterophyllopsida,
Sphenopsida,
Progymnospermopsida. The effect of this heterospory was that it presented a primary evolutionary advantage for these plants in colonizing land.[41] The simultaneous colonization of dry land and increase in plant body size that many lineages underwent during this time was likely facilitated by another parallel development: the replacement of the ancestral central cylinder of
xylem with more elongate, complex xylem strand shapes that would have made the plant body more resistant to the spread of drought-induced
embolism.[42]Tracheids, tapered cells that make up the xylem of vascular plants, first appear in the fossil record during the Early Devonian.[32] Woody stems evolved during the Devonian as well, with the first evidence of them dating back to the Early Devonian.[43] Evidence of root structures appears for the first time during the Late Silurian.[44] Further appearances of roots in the fossil record are found in Early Devonian lycophytes,[45] and it has been suggested that the development of roots was an adaptation for maximising water acquisition in response to the increase in aridity over the course of the Silurian and Devonian.[46] The Early Devonian also saw the appearance of complex subterranean
rhizome networks.[47]
Effect on atmosphere, soil, and climate
Deep-rooted vascular plants had drastic impacts upon soil, atmosphere, and oceanic oxygen composition. The Devonian Plant Hypothesis is an explanation about these effects upon biogeomorphic ecosystems of climate and marine environments.[6] A climate/carbon/vegetation model could explain the effects of plant colonization during the Devonian. Expansion of terrestrial Devonian flora modified soil properties, increasing
silicate weathering by way of
rhizosphere development as evidenced by pedogenic carbonates.[48][49] This caused atmospheric CO2 levels to fall from around 6300 to 2100 ppmv, although it also drastically reduced the albedo of much of Earth's land surface, retarding the cooling effects of this greenhouse gas drawdown.[50] The biological sequestration of so much carbon dioxide resulted in the beginning of the
Late Palaeozoic Ice Age at the terminus of the Devonian,[51][52][53] together with the tectonic uplift of the continent
Gondwana.[54]
Oxygen levels rose as a direct result of plant expansion.[50] With increased oxygenation came increased fire activity.[55] Earth's atmosphere first became sufficiently high in oxygen to produce wildfires in the Pridoli, when the first charcoal evidence of wildfires is recorded.[56] For most of the Early and Middle Devonian, the atmosphere was insufficiently oxygenated to enable significant fire activity.[57] By the late Famennian, however, oxygen levels were high enough to enable
wildfires to occur with regularity and on large scales,[58] something which had not been previously possible due to the paucity of atmospheric oxygen.[59]
The rise of trees and forests caused greater amounts of fine sediment particles to be retained on alluvial plains, increasing the complexity of meandering and braided fluvial systems. The greater complexity of terrestrial habitats facilitated the colonisation of the land by arthropods. Additionally, the increased weathering of phosphates and quantity of terrestrial humic matter increased nutrient levels in freshwater lakes, facilitating their colonisation by freshwater vertebrates. From these lakes, vertebrates would later follow arthropods in their conquest of the land.[60]
The Devonian explosion had global consequences on oceanic nutrient content and sediment cycling, which had led to the
Devonian mass extinction. The expansion of trees in the Late Devonian drastically increased biological weathering rates and the consequent riverine input of nutrients into the ocean.[61][62][63] The altering of soil composition created anoxic sedimentation (or black shales), oceanic acidification, and global
climate changes. This led to harsh living conditions for oceanic and terrestrial life.[64]
The increase in terrestrial plant matter in swamplands explains the deposits of coal and oil that would later characterize the
Carboniferous.[9]