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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A. Lukeneder et al. (2024):
Multi-proxy
record of the Austrian Upper Triassic Polzberg Konservat-Lagerstätte in light of the
Carnian Pluvial Episode. Open access,
Scientific Reports, 14.
See likewise
here
(in PDF).
S.A. Smith and J.M. Beaulieu (2024):
Ad fontes:
divergence-time estimation and the age of angiosperms. Open access,
New Phytologist.
"... When our results present a dramatically different view of life's history, such
as in the case of plant life, it may be more reasonable to consider errors in our model
or interpretation than to dismiss conflicting data outright. Like the iconoclasm of the
16th and 17th centuries, simplifying analyses and focusing on underlying biology
may lead to a clearer understanding of the evidence ..."
!
August von Gutbier (1835-1836):
Abdrücke
und Versteinerungen des Zwickauer Schwarzkohlengebirges und seiner Umgebungen.
Zwickau 1835-1836. In German.
Provided by R. Daber, J. Meyer and P.B. Wendt,
Botanischer Garten Berlin (Freie Universität Berlin). Excellent!
Note the
restored plates and
!
photographs
of Gutbier specimen.
Allgemeine Deutsche Biographie 10: 216-217.
August
von Gutbier (1798-1866). In German.
Y.L. Qiu and B.D. Mishler (2024):
Relationships
Among the Bryophytes and Vascular Plants: A Case Study in Deep-Time Reconstruction. Open access,
Diversity, 16. https://doi.org/10.3390/d16070426.
"... A tentative consensus, reached
ten years ago, suggested that bryophytes are a paraphyletic group, with liverworts being sister to all
other land plants and hornworts being sister to vascular plants
[...] A discussion is presented here on strengths and weaknesses of different types of
characters (morphological traits, nucleotide sequences, and genome structural arrangements) and
their suitability for resolving deep phylogenetic relationships ..."
C.C. Labandeira and R. Cenci (2024): Workshop: Insect-Plant Interaction Notes. In PDF, Conference: Ichnia 2024 - The 5th International Congress on Ichnology, Florianópolis, Brazil.
!
A.C. Scott (2024):
The
Anatomically preserved Early Carboniferous flora of Pettycur, Fife, Scotland. Open access,
Proceedings of the Geologists' Association, 135: 389–415.
"... At least 25 plant organ species are present representing more than 13 whole plant species
[...] It is shown also that a number of the plants may also be preserved as charcoal
[...] Of particular importance is the occurrence of true permineralised peats that provide
evidence of the botanical composition of the earliest peat-forming mire at a time
of rapid global change ..."
E. Kustatscher et al. (2024): Triassic macrofloras of the Udine Province (Eastern Southern Alps). In PDF, Gortonia, 45: 93-112.
J. Smerdon et al. (2023):
The historical
development of large-scale paleoclimate
field reconstructions over the
Common Era. Open access,
Reviews of Geophysics, 61. e2022RG000782. https://doi.org/10.1029/2022RG000782-
"... annually-resolved climate proxies, such as tree rings, ice cores, and corals,
when used in concert
with observational records, can provide information on how climate
conditions have changed over decades to
millennia. These proxies are also abundant enough over the last two
millennia to create reconstructions in both
space and time, or maps of climate conditions at seasonal or annual
intervals. These kinds of reconstructions
are called climate field reconstructions (CFRs) and we review their
scientific history back to the 1970s when
they were first attempted ..."
!
P. Cockx and R.C. McKellar (2024):
Bonebed
amber deposits: a review of taphonomy and palaeontological significance. Open access,
Evolving Earth, 2.
Note figure 1: Taphonomy of bonebed deposits and amber deposits.
! A. Champreux et al. (2024): How to map biomes: Quantitative comparison and review of biome-mapping methods. Open access, Ecological Monographs, 94.
S. Álvarez-Parra et al. (2024): Taphonomy and palaeoenvironmental interpretation of a new amber-bearing outcrop from the mid-Cretaceous of the Maestrazgo Basin (E Iberian Peninsula). In PDF, Spanish Journal of Palaeontology, 39.
A.C. Scott (2024):
Carboniferous
wildfire revisited: Wildfire, post-fire erosion and deposition in a
Mississippian crater lake. In PDF,
Proceedings of the Geologists' Association, 135: 416-437.
See likewiswe
here.
Note figure 6c–e. Scanning electron micrographs of charred Metaclepsydropsis.
!
Figure 13f-h: Scanning electron micrograph of charcoalified pteridosperm leaf
dissolved from Pettycur Limestone block.
D.G. Harbowo et al. (2024):
Microanalytical
approaches on the silicification process of wood fossil from Jasinga, West Java,
Indonesia. In PDF, Scientific Reports, 14.
See likewise
here.
"... our aim was to characterize the composition of silicified wood using
comprehensive microanalysis. The
methods utilized were XRF, ICP-MS, XRD, FTIR, and FE-EPMA ..."
A. Kuczumow et al. (2000): Investigation of petrified wood by synchrotron X-ray fluorescence and diffraction methods. In PDF, Spectrochimica Acta Part B: Atomic Spectroscopy, Volume 55, Number 10, 2 October 2000, pp. 1623-1633. See also here (PDF file).
!
Y. Pan et al. (2019):
Applications
of chemical imaging techniques in paleontology. Open access,
National Science Review, 6: 1040–1053: https://doi.org/10.1093/nsr/nwy107.
"... Chemical imaging techniques, based on a combination of microscopy and spectroscopy, are designed to analyse the composition and spatial distribution of heterogeneous chemical complexes within a sample. Over the last few decades, it has become an increasingly popular tool for characterizing trace elements, isotopic information and organic biomarkers (molecular biosignatures) found in fossils ..."
Wikipedia, the free encyclopedia:
Category:Fourier analysis.
Fourier-transform
infrared spectroscopy.
F.T. Winnie (2023; article starts on pdf page 11): Origin, Adaptations and Evolution of Land Plants. In PDF, Advanced Research in Biological Science, 5.
Diversity
Diversity is a peer-reviewed, open access journal on the science of biodiversity from molecules,
genes, populations, and species, to ecosystems and is published monthly online by MDPI.
J. Louys (2012; ed.):
Paleontology
in Ecology and Conservation. In PDF,
Springer Earth System Sciences, DOI 10.1007/978-3-642-25038-5_3,
This expired link is now available through the Internet Archive´s
Wayback Machine.
See also
here. Note especially:
!
Starting on PDF page 1: Chapter 1
Paleontology in Ecology and Conservation:
An Introduction (by J. Louys).
! Starting on PDF page 23: Chapter 3
Ecology Needs a Paleontological Perspective (by J.Louys, D.M. Wilkinson, and L.C. Bishop).
! Starting on PDF page 39: Chapter 4
Reconciling Scale in Paleontological
and Neontological Data: Dimensions of Time,
Space, and Taxonomy (by J.B. Bennington and M.F.J. Aronson).
!
P.K. Strother and W.A. Taylor (2024):
A
fossil record of spores before sporophytes. Open access,
Diversity, 16. https://doi.org/10.3390/d16070428.
Note figure 3: Stratigraphic distribution of cryptospore categories and early trilete spores.
M.M. Windell (2024):
A
Permian permineralised peat reveals high
spatial and temporal variation in plant
assemblage. In PDF.
Degree Project in Physical Geography and Quaternary Geography,
Stockholm University.
See here
as well.
Note figure 10: Reconstruction of the rift-valley-bound mid-Permian forest swamp ecosystem of East
Antarctica, at the beginning of autumn.
M. Boderau et al. (2024):
Morphological
and palaeoecological aspects of fossil insects unveiled by UV-A light. In PDF,
MethodsX, 13. ff10.1016/j.mex.2024.102794ff. ffinsu-04625219ff.
Note likewise
here.
"... we propose a user-friendly and
simple methodology based on UV-light to study insect fossils
[...] Our approach allows
the investigation of fossils using an affordable, compact, and portable UV-light source, along with
a simple and replicable low-cost protocol ..."
J. Schaeffer et al. (2024):
Paleobiological
implications of chevron pathology in the
sauropodomorph Plateosaurus trossingensis from
the Upper Triassic of SW Germany. Open access,
PLoS One, 19. e0306819. https://doi.org/10.1371/journal.pone.0306819.
See also:
New
insights into one of Europe’s oldest dinosaurs
(by Meike Rech, idw, August 01, 2024).
E. Larsén (2024):
Phylogeny
and macroevolution in Isoetes (Isoetales). In PDF,
Dissertation, Department of Ecology, Environment and Plant
Sciences, Stockholm University.
See here
as well.
J. Zeng et al. (2024):
End-Triassic
storm deposits in the lacustrine Sichuan Basin and their driving mechanisms. In PDF,
Science China Earth Sciences, 67.
See likewise
here.
!
D.P. Gifford (1981):
Taphonomy
and Paleoecology: A Critical Review of Archaeology's Sister Disciplines. In PDF,
Advances in Archaeological Method and Theory, 4: 365-438.
See here
as well.
Note figure 8.1: Schematic representation of the states through which a fossil
element passes and the processes that transfer it from one state to another.
"... taphonomy involves two distinct but necessarily related lines of investigation.
The first is devoted to studying observable contemporary processes involved in this
transition of organic remains from biosphere to lithosphere
[...] Properly pursued, taphonomy can provide paleoecologists with information about the
spatial, temporal, and biological factors involved in the formation of fossil assemblages ..."
S.M. Holland et al. (2024):
Stratigraphic
paleobiology. In PDF, Paleobiology 1–18.
https://doi.org/10.1017/pab.2024.2
See here
as well.
"... we present recent advances in six major
areas of stratigraphic paleobiology, including critical tests in the Po Plain of Italy,
mass extinctions and recoveries, contrasts of shallow-marine and nonmarine systems, the
interrelationships of habitats and stratigraphic architecture, large-scale stratigraphic
architecture, and the assembly of regional ecosystems ..."
Harald Immel, Institut für Paläontologie und Historische Geologie,
Ludwig-Maximilians-Universität,
München (Paläontologische Gesellschaft):
Literaturempfehlungen zur "Allgemeinen Paläontologie", and
Literaturempfehlungen zur "Historischen Geologie".
Textbook recommendations, in German.
Websites outdated. Links go to versions archived by the Internet Archive´s Wayback Machine.
!
A.C. Scott (2024):
Thirty
Years of Progress in Our Understanding of the Nature and Influence of Fire in
Carboniferous Ecosystems. In PDF, Fire, 7. 248. https://doi.org/10.3390/fire7070248.
See here
as well.
Note figure 7: The interpretation of the Viséan East Kirkton environment highlighting the role
of wildfire.
"... One of the basic problems was the fact that charcoal-like wood fragments, so often found
in sedimentary rocks and in coals, were termed fusain and, in addition, many researchers could
not envision wildfires in peat-forming systems. The advent of Scanning Electron Microscopy and
studies on modern charcoals and fossil fusains demonstrated beyond doubt that wildfire residues
may be recognized in rocks dating back to at least 350 million years ..."
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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