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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S. Lidgard and E. Kitchen (2025):
Living
Fossil: A Metaphor's Travels Across Popular Culture and the Foundations of Darwinian
Evolution and Anthropology. Free access,
Journal of the History of Biology, 58: 163–213.
See here
as well.
"... We explore the development and relationships of living
fossil applications, focusing principally on Darwin’s concept
In Origin, Darwin
deployed living fossils as exceptions that prove the rule of his
principles of natural selection and divergence ..."
T. Hazra et al. (2021): First fossil evidence of leaf-feeding caterpillars from India and their feeding strategies. Free access, Lethaia, 54: 891–905.
Plantscience4u:
A website that provides educational resources on plant science. Go for example to:
General Topics.
J.W. Schopf (2006):
Fossil
evidence of Archaean life. In PDF,
Transactions of the Royal Society, B 361: 869–885.
See likewise
here.
S. Müller et al. (2025):
Coating
of microscope slide labels: a possible solution for their long-term preservation. In PDF,
Natural History Collections and Museomics, 2: 1–9.
See here
as well.
S.K. Donovan and M. Riley (2013): The importance of labels to specimens: an example from the Sedgwick Museum. In PDF, The Geological Curator, 9: 509.
B.E. Boudinot et al. (2024): Et latet et lucet: Discoveries from the Phyletisches Museum amber and copal collection in Jena, Germany. In PDF, Dtsch. Entomol. Z., 71. DOI 10.3897/dez.71.112433.
P.N. Wyse Jackson (2013): Permanency of labelling inks: A 25-year experiment. In PDF, The Geological Curator, 9: 507.
J. Pross et al. (2006):
Delineating
Sequence Stratigraphic Patterns in Deeper Ramp Carbonates: Quantitative
Palynofacies Data from the Upper Jurassic (Kimmeridgian) of Southwest Germany. In PDF,
Journal of Sedimentary Research, 76: 524-538.
See here
as well.
J.M. Lukaye (2009): Biostratigraphy and Palynofacies of Four Exploration Wells from the Albertine Graben, Uganda. PDF file, adapted from oral presentation. American Association of Petroleum Geologists.
!
M.P. D'Antonio (2025):
Convergent
evolution of the developmental anatomy of leaf abscission: evidence from the arboreous
lycopsid Sigillaria. Free access,
Annals of Botany. ttps://doi.org/10.1093/aob/mcaf188.
"... we investigate using microscopy permineralized leaf cushions of the arboreous lycopsid
Sigillaria approximata with and without articulated leaves
[...] Despite the similarities between leaf abscission in
Lepidodendrales and leaf abscission in extant euphyllophytes,
these represent distantly related plant groups separated in time
by 300 million years ..."
ScienceDirect:
Paleobotany.
This website is created by ScienceDirect using heuristic and
machine-learning approaches to extract relevant information.
G. Geyer and J. Sell (2025): Norestheria (Spinicaudata, Crustacea): Morphology and its stratigraphical and geographic significance. Palaeontologia Electronica, 28. https://doi.org/10.26879/1564.
E.M. Friis et al. (2007): Phase-contrast X-ray microtomography links Cretaceous seeds with Gnetales and Bennettitales. PDF file, Nature, 450: 549-552. See also here (abstract).
!
H. Sanei et al. (2024):
Assessing
biochar's permanence: An inertinite benchmark. Free access,
International Journal of Coal Geology, 281.
"... This study applies the well-established optical and compositional
characteristics of inertinite maceral, long defined by organic petrology
and geochemistry disciplines, as a benchmark of the geological permanence
for biochar. The well-calibrated and standardized tools commonly
used by geologists for quantifying the level of organic carbon evolution
have been re-introduced as new methods for measuring the degree of
carbonization with respect to the inertinite benchmark ..."
L. Marynowski et al. (2007):
Biomolecules
preserved in ca. 168 million year old fossil conifer wood. PDF file,
Naturwissenschaften, 94: 228-236.
See here
as well.
J. Chu et al. (2025):
Occurrence
of wildfire in peat/coal forming periods and its influence on paleoclimate in the
Permo-Carboniferous. Open access,
Energy Exploration & Exploitation, 3. https://doi.org/10.1177/0144598725131424.
"... This article reviews the historical significance of wildfires during the
Permo-Carboniferous period
and their connection to charcoal, inertinite and polycyclic aromatic hydrocarbons ..."
Microsoft-Support:
Reduce
the file size of your PowerPoint presentations.
See here
as well.
In German.
Presentationload:
Optimize
PowerPoint File Size: 5 Tips for Reducing the Size of Your Files!
Adobe:
How
to compress PowerPoint files.
Büro-Kaizen:
PowerPoint
Dateien verkleinern/komprimieren und Speicherplatz sparen (Anleitung). In German.
Heise-Online:
PowerPoint
komprimieren - so verkleinern Sie Ihre Präsentation. In German.
J.A. Craig et al. (2025): ! True substrates from a Mississippian wetland: windows into the biogeomorphology of Visean tetrapod habitats (Tyne Limestone Formation, UK). Open access, Geological Society, London, Special Publications: 556: 343-372.
Wikipedia, the free encyclopedia:
Category:Terrestrial
biomes.
Category:Wetlands.
Category:Aquatic ecology.
!
Wetland.
Feuchtgebiet (in German).
Palustrine wetland.
S, Murthy et al. (2025):
Palynofloral
and geochemical evidence for Permian-Triassic transition from Talcher Coalfield,
Son-Mahanadi Basin, India: Insights into age,
palaeovegetation, palaeoclimate and palaeowildfire Free access,
Geoscience Frontiers, 16.
"... the present study analysed the palynology, palynofacies, organic geochemistry (biomarkers),
stable isotopes, and charcoal within the subsurface Gondwana deposits of the Kamthi
Formation (late Permian-early Triassic) ..."
R. Neregato and R. Rohn (2025):
A
New Late Permian Sphenophyte Strobilus in the Paraná Basin, Brazil. In PDF.
See here
as well.
V.A. Korasidis and B.E. Wagstaff (2025):
Cool-temperate
riparian floras in the Early Cretaceous rift valley of Victoria, Australia. Open access,
Alcheringa. https://doi.org/10.1080/03115518.2025.2489614.
Note figure 14: Reconstruction of cool-temperate rainforest and fluvial environments in southeast Australian during the late Albian.
"... we studied 291 palynological samples from 48 sites in the Otway and
Gippsland basins. Podocarpaceae represent the major component of the open canopy forests ..."
S. Kock and M.K. Bamford (2025):
Fossil
wood from the Permian-Triassic Beaufort Group of South Africa's Karoo Basin:
Implications for palaeoclimate. Free access,
Earth History and Biodiversity, 5.
"... Tree-growth rings act as high-resolution climate proxies because wood anatomy is directly related to water
uptake and tree growth. 190 silicified wood samples representing three taxa from the main Karoo Basin of South
Africa were analysed ..."
L. Liu et al. (2025):
Ordovician
marine Charophyceae and insights into land plant derivations. In PDF,
Nature Plants, 11.
See likewise
here.
Note figure 4: Morphological and palaeoecological reconstructions of
Tarimochara miraclensis gen. et sp. nov.
Climatic Change
Climatic Change is dedicated to the totality of the problem of climatic variability and change
- its descriptions, causes, implications and interactions among these.
M. Barbacka et al. (2025):
Late
Jurassic plant fossils from Wólka Baltowska (Holy Cross Mountains, Poland). Free access,
Annales Societatis Geologorum Poloniae, 95.
See likewise
here.
Newsbreak:
Was
Ellie Sattler Based on a Real Paleobotanist?
(by Mitul Biswas, 2025).
About the perception of (fictional) paleobotanists in the public. See also:
Ellie Sattler
(Wikipedia).
!
J.W. Clark and P.C.J. Donoghue (2025):
Uncertainty
in the timing of diversification of flowering plants rests with equivocal
interpretation of their fossil record.
R. Soc. Open Sci., 12: 242158. https://doi.org/10.1098/rsos.242158.
See likewise here.
"... We show that the disagreement between molecular and
palaeobotanical estimates is an artefact of interpretations of the fossil record
[...] Attention should be refocused on the history of stem-angiosperms in
which the body plan of this most successful lineage of land
plants was assembled ...
D. Quiroz-Cabascango et al. (2025):
Earliest
Jurassic plant assemblages from Sweden reveal a low-diversity ginkgoalean and
cheirolepid flora dominating the post-extinction landscape. Free access,
Annals of Botany. https://doi.org/10.1093/aob/mcaf143.
Note figure 9A: Centimetre-scale charcoalified wood fragments in feldspathic sandstone.
"The low-diversity post-extinction recovery forests of the earliest Jurassic were dominated
by ginkgoopsids, cheirolepid conifers and ferns, growing under seasonal mesothermal conditions.
Dispersed charcoal indicates wildfires were present in the landscape at this time ..."
H. Nguyen and V.K. Huong (2025):
Integrating
Plant Fossil Proxies and Biomarkers to Reconstruct Deep-Time Paleoclimate,
Paleoecology, and Evolutionary Dynamics. In PDF,
Scientific Research Journal of Biology and Life Science, 3.
"... This paper reviews and synthesizes evidence from plant fossil records—particularly
fossil leaves and resins— and their associated biomarkers, along with geological
and paleogeographic data, to reconstruct past climates and ecosystems ..."
B. Adroit et al. (2025): Editorial: Changes in plant–herbivore interactions across time scales: bridging paleoecology and contemporary ecology. In PDF, Front. Ecol. Evol. 12: 1539173. doi: 10.3389/fevo.2024.1539173
S.D. Burgess and B.A. Black (2025):
The
Anatomy and Lethality of the Siberian Traps Large Igneous Province. Free access,
Annual Review of Earth and Planetary Science, 53: 567–945.
"... This review provides a summary of recent
advances and key questions regarding the Siberian Traps in an effort to
illuminate what combination of factors made the Siberian Traps a uniquely
deadly LIP ..."
S. Pla-Pueyo and E.H. Gierlowski-Kordesch (2025):
Wetlands
as environments of early human occupation: A new classification
for freshwater palaeowetlands. Open access,
The Depositional Record. DOI: 10.1002/dep2.327.
"... A new classification for inland freshwater palaeowetlands, with a focus on carbonate
wetlands, is proposed here, recognising key features that
an be preserved in the fossil record ..."
D.M. Njoroge et al. (2025):
The
effects of invertebrates on wood decomposition across the world. In PDF,
Biological Reviews, 100: 158-171. https://doi.org/10.1111/brv.13134.
See likewise
here.
"... we investigated what drives the invertebrate effect on wood decomposition worldwide.
Globally, we found wood decomposition rates were on average approximately 40% higher when
invertebrates were present compared to when they were excluded. This effect was most pronounced
in the tropics, owing mainly to the activities of termites ..."
!
E. Mujal et al. (2025):
Triassic
terrestrial tetrapod faunas of the Central European Basin, their stratigraphical distribution, and their palaeoenvironments. Free access,
Earth-Science Reviews, 264.
!
Note figure 1: Palaeogeography of the Triassic of Pangaea and the Central European
Basin (CEB), and stratigraphy of the German Triassic.
"... A review of the fossil evidence permits the recognition of new patterns of diversity for various clades during the recovery period following the end-Permian mass extinction
[...] the CEB [Central European Basin] provides an excellent record for studying the
evolution of Triassic terrestrial tetrapod faunas along with environmental changes over much of that period ..."
!
S. Magallón et al. (2025):
A
metacalibrated time-tree documents the early rise of flowering
plant phylogenetic diversity. Free access,
New Phytologist, 207: 249-479.
Note figure 1: Molecular and fossil-based estimates of angiosperm age.
"... A large number of fossil-derived calibrations and a confidence
interval on angiosperm age have been combined in relaxed clock
analyses to provide a time-frame of angiosperm evolution. The
maximum age of the onset of diversification of angiosperms into
their living diversity has been calculated with high confidence to
lie in the Early Cretaceous ..."
K. Opitek et al. (2025):
Morphology
and mode of life of a peculiar Devonian microconchid tubeworm
Aculeiconchus from Wyoming, USA. Open access, Lethaia, 57.
https://doi.org/10.18261/let.57.4.8.
!
Note figure 7: Artists’ reconstructions of a Late Devonian estuary habitat showing
non-calcified algae encrusted by abundant microconchids.
L. Azevedo-Schmidt et al. (2025):
Advancing
terrestrial ecology by improving cross-temporal research and collaboration. Free access,
BioScience, 75: 15–29.
"... we compared two previous studies
[...] a path forward is outlined, focusing on education and
training, research infrastructure, and collaboration ..."
F.R. Badenes-Pérez (2025): Plant–Insect Interactions: Host Plant Resistance, Biological Control, and Pollination. Open access, Plants, 14. https://doi.org/10.3390/plants14101488.
X. Delclòs et al. (2025): Cretaceous amber of Ecuador unveils new insights into South America's Gondwanan forests. Free access, Communications Earth & Environment, 6. See likewise here. (in PDF).
J. Lee (2025): Deep-Time Evolution of Tubers in Equisetum and the Broader Sphenophytes. Abstract, International Journal of Plant Sciences, 186.
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This index is compiled and maintained by
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