User:Stocksdale/sandbox5

Stocksdale/sandbox5; Temporal range: Late Carboniferous–Permian PreꞒ Ꞓ O S D C P T J K Pg N
	A transverse section through a Psaronius stem. ~12cm across.
	An equivalent section through a modern tree fern. ~6cm across.
Scientific classification
Kingdom:	Plantae
Division:	Pteridophyta
Class:	Marattiopsida
Order:	Marattiales
Family:	Psaroniaceae
Genus:	Psaronius

Psaronius was a Marattialean tree fern which grew to 10m in height, and is associated with leaves of the organ genus Pecopteris and other extinct tree ferns. Originally, Psaronius was a name for the petrified stems, but today the genus is used for the entire tree fern. Psaronius tree fern fossils are found from the Carboniferous through the Permian.

Etymology[edit]

The word Psaronius comes from the Greek ψαρονιος (psaronius, precious stone) the root of which is ψαρον (psaron, a starling bird.] The stone was used for ornamental purposes in Europe and acquired the name for its resemblance to the speckled pattern of the starling. In Germany, the stone was called staarstein. And in English, it was called either starry-stone or starling stone.^[1]

Description[edit]

Like many extinct trees, psaronius is known by various individual fossil parts that are not always found together. The main parts include: the root mantle, the stem, the fronds, the coziers (fiddleheads), and leaves with spores.

Tubiculites, the fossilized impressions of the rootlets of the Carboniferous fern called Psaronius.

Root Mantle[edit]

An unusual feature is that Psaronius did not have a true trunk, but had a massive root mantle formed by hundreds of rootlets. These rootlets are referred to as adventitious because they are appearing in an atypical location. These adventitious roots originate in a central stem high in the tree. This central stem becomes smaller lower in the tree so that at the base the mantle is comprised entirely of roots. In some specimens, this mantle is over 1.0 m in diameter at the base of the tree. The fossilized wood of this root mantle is simply referred to as Psaronius. The side impressions of these adventitious roots are referred to as Tubiculites by the French Geologist François Cyrille Grand'Eury in 1877.^[2]

An Ecosystem in the Psaronius Root Mantle[edit]

Like modern tree ferns, Psaronius included other plant species growing in the root mantle. It has been determined through cross-sections of petrified Psaronius, that various vining and epiphytic plants were growing within the tree fern. Some Carboniferous plant species are only known from their fossilized remains within these root mantles. Some of these that have been studied extensively are the epiphyte Botryopteris, the vining climber Ankyropteris and the small climbing ferns called Tubicaulis.^[3] ^[4]

^[5]

Fronds and Leaves[edit]

The leaves most often associated with Psaronius are those known as Pecopteris, but some species of Psaronius bore Sphenopteris foliage. Fossil of the croziers (or fiddleheads) of the fern fronds have been found. They sometimes go by the name Spiropteris. The study of croziers associated with psaronius wood have been used to determine foliage associations. The fronds were often bipinnate and sometimes tripinnate. Other leaf taxon associated with Psaronius include: Asterotheca, Acitheca, Remia and Radstockia.^[6]

Pecopteris polymorpha
Pecopteris arborescens
Pecopteris villosa

Leaf Scar[edit]

The bases where the leaves attached were thick to carry the weight of fronds that could attain the size of 2 to 3 meters. stem scars. When fronds abscised from Psaronius , they left elliptical scars on the surface of the stem. Fossils of these leaf scars appear in different arrangements which may indicate different species of trees. These scars are known as Caulopteris, Megaphyton, Hagiophyton, and Artisophyton based on the four main arrangement patterns.^[6]^[7]

Psaronius stem surface petiole base configurations. A. Caulopteris . B. Megaphyton . C. Hagiophyton . D. Artisophyton

Geological timeframe[edit]

Climate change and Psaronius dominance[edit]

A change in terrestrial tropical wetland vegetation has been documented across the middle–late Pennsylvanian transition. This is sometimes referred to as the Carboniferous rainforest collapse. However, it is not precisely a collapse but more of a shift in the species composition of the Carboniferous forests.

The biotic pattern is a rapid, essentially catastrophic change from wetland vegetation rich in, or dominated by, giant lycopsid trees, seed ferns and tree ferns, to one dominated by tree ferns, with subdominant seed ferns; the change also includes significant turnover in species and genera within the major evolutionary lineages involved

In abstract, the middle–late Pennsylvanian changes are these: middle Pennsylvanian wetland environments were dominated for over 9 million years by a complex of plants consisting, by the end of the middle Pennsylvanian, of numerous species and genera of arborescent lycopsids, seed ferns, cordaitalean seed plants, calamitean sphenopsids and marattialean tree ferns. During the middle–late Pennsylvanian transition, the dominance patterns in wetland vegetation changed dramatically throughout the European and North American equatorial basins. Well over half the species typical of middle Pennsylvanian wetlands went extinct, based on both adpression and coal-ball macrofossil data (e.g. DiMichele & Phillips, 1996; Blake et al., 1999). In the late Pennsylvanian, tree ferns dominated most wetland settings (e.g. Falcon-Lang, 2006; Willard et al., 2007); they were both diverse and abundant. On average seed ferns were subdominant, with only one major genus of lycopsid tree, Sigillaria, remaining as a significant element. Calamiteans continued to play a relatively minor role, as did cordaitaleans. This change did not happen in wetland basins of far eastern Pangaea, on the Chinese microcontinents, where middle Pennsylvanian type floras persisted until the later Permian (Hilton & Cleal, 2007). ^[8]

^[9]

^[10]

Carboniferous rainforest collapse[edit]

In the middle of this larger transition that was occurring over millions of years was a dramatic extinction event that is sometimes called the Carboniferous Rainforest Collapse.

Similar Marattialean ferns[edit]

Tietea singularis

Tuvichapteris solmsii

Relationship to modern ferns[edit]

Psaronius is in included in the fern family Marattiaceae. Living representatives of this family include many large ferns but none are a 'tree form' like Psaronius. Recent molecular studies indicate that this group of ferns have a very old lineage and may be a sister group to the horsetails Equisetum. Modern tree ferns have many similarities to Psaronius but are in a younger fern family, the Cyatheales.

References[edit]

^ Whitney, W.D. (1906). The Century Dictionary and Cyclopedia. Century Company. p. 4813.
^ Grand'Eury, François Cyrille (1877). Mémoire sur la flore carbonifère du département de la Loire et du centre de la France: étudiée aux trois points de vue, botanique, stratigraphique et géognostique. Imprimerie nationale. p. 98,102.
^ Rößler, Ronny (2000). "The late Palaeozoic tree fern Psaronius — an ecosystem unto itself". Review of Palaeobotany and Palynology. 108: 55–74.
^ DiMichele, William A.; Phillips, Tom L. (2002). "The ecology of Paleozoic ferns" (PDF). Review of Palaeobotany and Palynology (119): 143–159.
^ AmericanJournaolfBotany78(6):782-788. 1991. BOTRYOPTERIS FORENSIS (BOTRYOPTERIDACEAE), A TRUNK EPIPHYTE OF THE TREE FERN PSARONIUS' GAR W. ROTHWELL DepartmenotfBotanyO,hioUniversityA,thensO,hio45701
^ ^a ^b Taylor, Thomas N; Taylor, Edith L; Krings, Michael (2009). Paleobotany: The biology and evolution of fossil plants. ISBN 978-0-12-373972-8.
^ Pfefferkorn, H. W. (1976). "Pennsylvanian tree fern compressions Caulopteris , Megaphyton , and Artisophyton". Illinois State Geological Survey Circular (492): 1 – 31.
^ DiMichele, W.A., and Phillips, T.L. (1996). "Climate change, plant extinctions and vegetational recovery during the Middle-Late Pennsylvanian transition: The case of tropical peat-forming environments in North America". Biotic recovery from mass extinction events: Geological Society of London Special Publication. {{cite journal}}: |format= requires |url= (help)CS1 maint: multiple names: authors list (link)
^ DiMichele, W.A., Cecil, B., Montanez, I.P., and Falcon-Lang, H.J. (2010). "Cyclic changes in Pennsylvanian paleoclimate and it effects on floristic dynamics in tropical Pangaea". International Journal of Coal Geology. 83 (2–3): 329–344. doi:10.1016/j.coal.2010.01.007. {{cite journal}}: |format= requires |url= (help)CS1 maint: multiple names: authors list (link)
^ DiMichele, W.A., Montañez, I.P., Poulsen, C.J., Tabor, N.J. (2009). "Climate and vegetational regime shifts in the late Paleozoic ice age earth". Geobiology. 7: 200–26. {{cite journal}}: Text "doi: 10.1111/j.1472-4669.2009.00192.x." ignored (help)CS1 maint: multiple names: authors list (link)

External links[edit]

Category:Marattiopsida Category:Prehistoric plants Category:Carboniferous life

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[1] Whitney, W.D. (1906). The Century Dictionary and Cyclopedia. Century Company. p. 4813.

[2] Grand'Eury, François Cyrille (1877). Mémoire sur la flore carbonifère du département de la Loire et du centre de la France: étudiée aux trois points de vue, botanique, stratigraphique et géognostique. Imprimerie nationale. p. 98,102.

[3] Rößler, Ronny (2000). "The late Palaeozoic tree fern Psaronius — an ecosystem unto itself". Review of Palaeobotany and Palynology. 108: 55–74.

[4] DiMichele, William A.; Phillips, Tom L. (2002). "The ecology of Paleozoic ferns" (PDF). Review of Palaeobotany and Palynology (119): 143–159.

[5] AmericanJournaolfBotany78(6):782-788. 1991. BOTRYOPTERIS FORENSIS (BOTRYOPTERIDACEAE), A TRUNK EPIPHYTE OF THE TREE FERN PSARONIUS' GAR W. ROTHWELL DepartmenotfBotanyO,hioUniversityA,thensO,hio45701

[Thomas-6] Taylor, Thomas N; Taylor, Edith L; Krings, Michael (2009). Paleobotany: The biology and evolution of fossil plants. ISBN 978-0-12-373972-8.

[7] Pfefferkorn, H. W. (1976). "Pennsylvanian tree fern compressions Caulopteris , Megaphyton , and Artisophyton". Illinois State Geological Survey Circular (492): 1 – 31.

[8] DiMichele, W.A., and Phillips, T.L. (1996). "Climate change, plant extinctions and vegetational recovery during the Middle-Late Pennsylvanian transition: The case of tropical peat-forming environments in North America". Biotic recovery from mass extinction events: Geological Society of London Special Publication. {{cite journal}}: |format= requires |url= (help)CS1 maint: multiple names: authors list (link)

[9] DiMichele, W.A., Cecil, B., Montanez, I.P., and Falcon-Lang, H.J. (2010). "Cyclic changes in Pennsylvanian paleoclimate and it effects on floristic dynamics in tropical Pangaea". International Journal of Coal Geology. 83 (2–3): 329–344. doi:10.1016/j.coal.2010.01.007. {{cite journal}}: |format= requires |url= (help)CS1 maint: multiple names: authors list (link)

[10] DiMichele, W.A., Montañez, I.P., Poulsen, C.J., Tabor, N.J. (2009). "Climate and vegetational regime shifts in the late Paleozoic ice age earth". Geobiology. 7: 200–26. {{cite journal}}: Text "doi: 10.1111/j.1472-4669.2009.00192.x." ignored (help)CS1 maint: multiple names: authors list (link)

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