An annotated collection of pointers
to information on palaeobotany
or to WWW resources which may be of use to palaeobotanists
(with an Upper Triassic bias).
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!
J.M. Galloway and S. Lindström (2023):
Impacts
of large-scale magmatism on land plant ecosystems. Open access,
Elements, 19: 289–295.
! Note figure 1: Summary figure of changes in the diversity of land
plants over geological time.
Figure 2: Flow chart showing the myriad of ways large-scale magmatism may impact land plants.
"... Emplacement of large igneous
provinces (LIPs) is implicated in almost every mass extinction and smaller
biotic crises in Earth’s history, but the effects of these and other large-scale
magmatic events on terrestrial ecosystems are poorly understood
[...] We review existing palynological literature to
explore the direct and cumulative impacts of large-scale magmatism, such as
LIP-forming events, on terrestrial vegetation composition and dynamics over geological time ..."
M. Coiro et al. (2024):
Parallel
evolution of angiosperm-like venation in Peltaspermales: a reinvestigation
of Furcula. Open access,
New Phytologist,
doi: 10.1111/nph.19726.
"... Although a hierarchical-reticulate venation also occurs in some groups of extinct seed
plants, it is unclear whether these are stem relatives of angiosperms
[...] We further suggest that the evolution of hierarchical venation systems in the early Permian,
the Late Triassic, and the Early Cretaceous represent ‘natural experiments’ that might help
resolve the selective pressures enabling this trait to evolve ..."
Emanuele Di Lorenzo,
Georgia Institute of Technology, Atlanta, Georgia:
Early
Earth and the Origins of Life.
Powerpoint presentation.
! H. Tralau (1968): Evolutionary trends in the genus Ginkgo. Free access, Lethaia, 1: 63-101. https://doi.org/10.1111/j.1502-3931.1968.tb01728.x.
A.A. Pavlov et al. (2000):
Greenhouse
warming by CH4 in the atmosphere of early Earth. In PDF,
Journal of Geophysical Research, 105.
See
here as well.
!
Sandra Niemirowska, Warsaw:
Petrified Wood.
Various species of fossilized wood taken under the microscope and shown in tomograms.
Worth checking out:
!
Anatomical
details under the stereoscopic optical microscope and scanning electron microscope.
Gallery
of petrified wood.
A collection of petrified wood arranged in order of locations.
Stanley M. Awramik,
Department of Earth Science, University of California, Santa Barbara:
!
The
Record of Life on
the Early Earth.
Powerpoint presentation.
K. Hantsoo et al. (2024): Trends in estuarine pyrite formation point to an alternative model for Paleozoic pyrite burial. Open access, Geochimica et Cosmochimica Acta, 374: 51-71.
!
T.O. Akinsanpe et al. (2024):
Molecular
and mineral biomarker record of terrestrialization in the Rhynie Chert. Free access,
Palaeogeography, Palaeoclimatology, Palaeoecology, 640.
"... a wealth of fossil evidence is preserved in the Lower Devonian Rhynie Chert
lagerstätte, which is consequently considered to be the world's oldest
preserved terrestrial ecosystem
[...] In addition to organic biomarkers, the chert contains mineralogical characters
which imply biological activity, including pyrite framboids, strongly leached
monazite and garnet, and pitted micas similar to grains altered by modern fungi.
C.M. Berry and J.E.A. Marshall (2015): Lycopsid forests in the early Late Devonian paleoequatorial zone of Svalbard. Free access, Geology, 43: 1043-1046.
S. Salzman et al. (2024):
New
insights on cycad biology and evolution. In PDF.
See likewise
here.
"... we present the most recent advances in cycad research on land plant evolution,
the evolution and
mechanisms of insect pollination and herbivory, the biochemical basis of symbiosis,
microbial symbionts, and
plant genomics ..."
T.B. Dos Santos et al. (2024): Plant interactions with arthropods and pathogens at Sanzenbacher Ranch, early Permian of Texas, and implications for herbivory evolution in Southwestern Euramerica. Free access, Front. Ecol. Evol., Sec. Biogeography and Macroecology, 12. https://doi.org/10.3389/fevo.2024.1368174.
! H. Boukhamsin et al. (2023): Early Cretaceous angiosperm radiation in northeastern Gondwana: Insights from island biogeography theory. Free access, Earth-Science Reviews, 242.
Mesozoic
(Magnolia Press, Auckland, New Zealand).
Mesozoic (free online access) is an interdisciplinary journal dedicated to
the study of Earth and life evolution
during the Mesozoic Era.
G Roghi et al. (2022):
An
Exceptionally Preserved Terrestrial Record of LIP Effects on Plants in the
Carnian (Upper Triassic) Amber-Bearing Section of the
Dolomites, Italy. In PDF,
Frontiers in Earth Science.
Note figure 1: Pangaean floristic subprovinces during the Late Triassic.
!
Fig. 6: Fossil plant remains and palynomorphs enclosed in the amber droplets.
X.-D. Gou and Z. Feng (2024): Checklist of the Jurassic wood (updated March 2024). Open access, Mesozoic, 1.
C. Salcido et al. (2024):
Research
put into action: How a fossil inventory informed
paleontological resource monitoring efforts preceding road
construction at Theodore Roosevelt National Park. Free access,
Parks Stewardship Forum.
"... Theodore Roosevelt National Park (THRO) in western North Dakota that comprises badlands
[...] Results of monitoring
included the discovery of new paleontological material, including bird material and
well-preserved angiosperm fossils ..."
J. Carrion et al. (2024):
Greening
a lost world: Paleoartistic investigations of the early Pleistocene vegetation landscape
in the first Europeans’ homeland. Free access,
Quaternary Science Advances, 14.
"... we present paleoartistic renderings depicting vegetation landscapes around the Orce
Archaeological Zone (OAZ), encompassing sites dating from 1.6 to 1.2 million years ago
during the Early Pleistocene
[...] This essay visually represents the coexistence of mesophytic, thermophytic, and
xerophytic plant communities within a glacial refugium of woody species ..."
!
D. Jablonski and S.M. Edie (2023):
Perfect
storms shape biodiversity in time and space. Free access,
Evolutionary Journal of the Linnean Society, 2.
"... Many of the most dramatic patterns in biological diversity are created by
“Perfect Storms” —rare combinations of mutually reinforcing factors that push origination,
extinction, or diversity accommodation to extremes
[...] The Perfect Storms perspective may allow more nuanced and
specific applications of our characterization of past events to the
present day, even if today’s combination of pressures is in some
ways unprecedented ..."
B. Sterner (2023):
Norms
of evidence in the classification of living fossils. In PDF,
Frontiers in Ecology and Evolution, 11: 1198224.
doi: 10.3389/fevo.2023.1198224.
See also here.
"... Some species have held fast for millions of years as constants in a changing world. Often called
“living fossils,” these species capture sci See also entific and public interest by showing us
the vestiges of an earlier world.
[...] While debates over the definition of the living fossil concept may appear fruitless,
I&xnbsp;suggest they can be&xnbsp;productive insofar as the debate leads to clarified and improved evidential
standards for classification ..."
G.V. Middleton et al. (eds.; 2003):
Encyclopedia
of Sediments and Sedimentary Rocks. In PDF,
Kluwer Academic Encyclopedia of Earth Sciences Series.
See likewise
here.
I. Werneburg (2023):
Fossile Pflanzen.
Die Paläobotanische Schausammlung in Tübingen (1983 bis 2017). PDF file, in German.
Chelyops,
Berichte aus der Paläontologischen Sammlung in Tübingen, 2: 139-178.
!
Note the depicted specimens in the photo documentation (plates) on pages 156-178 (PDF pages 18-40).
I. Werneburg (2021): Ein Stück Kulturgeschichte. Zur Entwicklung der Paläontologischen Sammlung Tübingen. PDF file, in German. In: B. Engler and E. Seidl (eds.): Aus der Tiefenzeit. Die Paläontologische Sammlung der Universität Tübingen. Schriften des Museums der Universität Tübingen MUT, 20.
I. Werneburg and M. Böhme (2018):
The
Palaeontologial Collection of Tübingen. In PDF.
Note also
here.
In L.A. Beck, U. Joger (eds.), Paleontological Collections of Germany,
Austria and Switzerland, Natural History Collection. Springer.
https://doi.org/10.1007/978-3-319-77401-5_52. Worth checking out:
Table of contents
(57 chapters).
C. Del Rio (2023):
Replicability
in palaeobotany: Toward a standardisation of citation of extant material. In PDF,
Review of Palaeobotany and Palynology, 317.
See likewise
here.
"... there is no standard for citing herbarium sheets, personal collections, or field pictures
of specimens. Here, I propose a simple citation guideline for all these cases ..."
!
J.H.A. Van Konijnenburg-van Cittert et al. (2021):
The
Rhaetian flora of Wüstenwelsberg, Bavaria, Germany: Description
of selected gymnosperms (Ginkgoales, Cycadales, Coniferales) together
with an ecological assessment of the locally prevailing vegetation. Free access,
Review of Palaeobotany and Palynology, 288.
"... This paper describes the ginkgoaleans (Ginkgoites) and conifers (Palissya, Stachyotaxus,
Schizolepis) of the Rhaetian flora from Wüstenwelsberg, as well as a new species of
the cycad Becklesia
[...] A comparison with other Northern Hemisphere plant assemblages demonstrates a high similarity
with the Rhaetian floras from Jameson Land (Greenland) and Scania (Sweden) but significant
differences to the Hettangian floras from adjacent areas in Franconia ..."
T.E. Pedernera et al. (2023): The influence of volcanic activity and trophic state on plant taphonomic processes in Triassic lacustrine-deltaic systems of western Gondwana. Free access, Lethaia, 54: 521–539.
D. Dimitrov et al. (2023):
Diversification
of flowering plants in space and time. Free access,
Nature Communications, 14.
"... Using a newly generated genus-level phylogeny and global distribution data for 14,244
flowering plant genera, we describe the diversification dynamics of angiosperms
through space and time. Our analyses show that diversification rates
increased throughout the early Cretaceous and then slightly decreased or
remained mostly stable until the end of the Cretaceous–Paleogene mass
extinction event 66 million years ago. After that, diversification rates
increased again towards the present ..."
J. Marmi et al. (2023): Evolutionary history, biogeography, and extinction of the Cretaceous cheirolepidiaceous conifer, Frenelopsis. Free access, Evolving Earth, 1.
L. Azevedo-Schmidt et al. (2024):
Ferns
as facilitators of community recovery following biotic upheaval. Open access,
BioScience. https://doi.org/10.1093/biosci/biae022.
! Note figure 1: Time-calibrated fern phylogeny
[shows additionally major extinction events with and without fern spike].
See also
here.
"... The competitive success of ferns has been foundational to hypotheses about terrestrial
recolonization following biotic upheaval, from wildfires to the Cretaceous–Paleogene asteroid
impact (66 million years ago). Rapid fern recolonization in primary successional environments has been hypothesized
to be driven by ferns’ high spore production and wind dispersal
[...] We propose that a competition-based view of ferns is outdated and in need of reexamination ..."
! A.H. Knoll and K.J. Niklas (1987): Adaptation, plant evolution, and the fossil record. Free access, Review of Palaeobotany and Palynology, 50: 127-149.
Y.-F. Li et al. (2024): New material of Coniopteris simplex from the Middle Jurassic of the Ordos Basin, Inner Mongolia, China and implications on its spatio-temporal distribution and paleogeography. Free access, Journal of Palaeogeography.
Wikipedia, the free encyclopedia:
Estella Leopold
(1927-2024).
Nature: Estella
Bergere Leopold (1927–2024), passionate environmentalist who traced changing ecosystems.
Susan Flader:
Biographical Portrait - Estella
Bergere Leopold. In PDF,
Forest History Today.
I. Vilovic et al. (2023):
Variations
in climate habitability parameters and their effect on Earth's biosphere
during the Phanerozoic Eon. Open access,
Scientific Reports, 13.
https://doi.org/10.1038/s41598-023-39716-z
Note figure 5: Phanerozoic biodiversity curves.
"... We compiled environmental and biological
properties of the Phanerozoic Eon from various published data sets and conducted a correlation
analysis to assess variations in parameters relevant to the habitability of Earth’s biosphere
We showed that there were several periods with a highly thriving biosphere, with one
even surpassing present day biodiversity and biomass. Those periods were characterized by increased
oxygen levels and global runoff rates ..."
C. Mckean et al. (2023):
New
taphonomic and sedimentological insights into the preservation of high-relief Ediacaran
fossils at Upper Island Cove, Newfoundland. Open access,
Lethaia, 56: 1–17.
Note figure 11: General taphonomic model.
Figure 12: Epirelief variation model.
!
M. Barbacka (1994):
Komlopteris
Barbacka, gen. nov., a segregate from Pachypteris Brongniart. In PDF,
Review of Palaeobotany and Palynology, 83: 339-349.
See likewise
here.
Keywords: Paleobotany, Palaeobotany, Paläobotanik, Paleophytologist, Paleophytology, Palaeophytologist, Palaeophytology, Paleobotánica, Paléobotanique, Paleobotânica, Paleobotanico, Palaeobotanica, Paleobotanika, Paleobotaniky, Paleobotanikai, Paleobotaniikka, Paleontology, Palaeontology, Paläontologie, Paleobotánica, Paleontológico, Paleobotânicos, Paleobotaników, Botany, Fossil Plants, Paleovegetation, Palaeovegetation, Palaeophyticum, Paleophyticum, permineralized plants, petrified, cuticle, cuticles, charcoal, Palynology, Palynologie, Taphonomy, Tafonomía, paleosoil, palaeosoil, mesophytic, mesophyticum, Paläovegetation, Pflanzenfossilien, Evolution, Phylogeny, Triassic, Trias, Triásico, Keuper, Ladinian, Carnian, Norian, Rhaetian, Index, Link Page.
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This index is compiled and maintained by
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