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. Pérez-Huerta et al. (2018):
Understanding
biomineralization in the fossil record. In PDF,
Earth-Science Reviews, 179: 95-122.
Note here
as well.
G. Geyer et al. (2024) The End of the ‘Living Fossil’ Tale? A New Look at Triassic Specimens Assigned to the Tadpole Shrimp Triops cancriformis (Notostraca) and Associated Phyllopods from the Vosges Region (Eastern France). Free access, Papers in Palaeontology, 10: 1-31.
!
J. Sremac et al. (2024):
Marine
microfossils: Tiny archives of ocean changes through deep time. Free access,
AIMS Microbiology, 10: 644–673.
DOI: 10.3934/microbiol.2024030.
Note figure 15: The summary of the applications of microfossils in biostratigraphy,
paleoecology and the study of raw materials.
"... The most common marine fossil groups studied by micropaleontologists are cyanobacteria,
coccolithophores, dinoflagellates, diatoms, silicoflagellates, radiolarians, foraminifers,
red and green algae, ostracods, and pteropods
[...] By studying microfossils, paleontologists depict the age of the rock and
identify depositional environments ..."
!
I.J. Glasspool and R.A. Gastaldo (2024):
Through
fire, and through water, an abundance of Mid-Devonian charcoal. Open access,
Palaios, 39: 301–322.
Note figure 15: Uncalibrated and luminosity modified, oil immersion, reflected light
images of Trout Valley mesofossil;
see especially figure E:
!
The internal anatomy of a hooked-appendage shaft showing cell-wall lamination
and separation, and with many cells show brittle fracture bogen structures.
"... Charcoalified mesofossils recovered
from the Emsian–Eifelian Trout Valley and St. Froid Lake formations of Maine
are direct evidence of wildfires
[...] we provide a reconstruction of this Middle Devonian
landscape and its flora in which lightning generated by post-dry season storms ignited wildfires that propagated
through an extensive psilophyte-dominated litter ..."
J.M. Drovandi et al. (2024):
The
southwesternmost record of late Silurian (Pridolian) early land plants of Gondwana. Open access,
Scientific Reports.
See likewise
here.
B.A. Lloyd et al. (2024): CuticleTrace: A toolkit for capturing cell outlines from leaf cuticle with implications for paleoecology and paleoclimatology. Free access, Applications in Plant Sciences, 12.
R.V. Vofély et al. (2019): Of puzzles and pavements: a quantitative exploration of leaf epidermal cell shape. Free access, New Phytologist, 221: 540-552.
J. McCoy et al. (2024): Temperate to tropical palaeoclimates on the northwest margin of Europe during the middle Cenozoic. Open access, Palaeontologia Electronica, 27. https://doi.org/10.26879/1349
!
J. Bevendorff et al. (2024):
Is
Google Getting Worse? A Longitudinal Investigation of SEO Spam in Search Engines
European Conference on Information Retrieval.
See likewise here.
"... Many users of web search engines have been complaining
in recent years about the supposedly decreasing quality of search results
[...] We monitored Google, Bing and DuckDuckGo for a year on 7,392 product
review queries. Our findings suggest that all search engines have
significant problems with highly optimized (affiliate) content ..."
Also worth checking out:
It's
not just you, Google Search really has gotten worse.
A new study by German researchers found that Google Search is plagued with SEO spam.
By Meera Navlakha, Mashable, January 18, 2024.
PC Magazine:
Go
Beyond Google: The Best Alternative Search Engines for 2024.
By Michael Muchmore, August 14, 2024.
Forbes:
10
Alternative Search Engines To Use Instead Of Google.
By Barry Collins.
Dorik (an all-in-one website building platform):
25+
Best Google Alternative Search Engines to Use in 2024.
Looking for an alternative search engine to Google? Here are the 26 best alternative search engines you
can use instead of Google.
By Zaki Rezwana Chowdhury, September 2024.
Chip:
Alternative
Suchmaschinen: Besser suchen ohne Google.
In German (by Marianne Westenthanner, March 2024).
A. Palandacic et al. (2024): An annotated catalogue of selected historical type specimens, including genetic data, housed in the Natural History Museum Vienna. Free access, ZooKeys, 1203: 253–323.
Y. Yang et al. (2024): The Systematics and Evolution of Gymnosperms with an Emphasis on a Few Problematic Taxa. Open access, Plants, 13. https://doi.org/10.3390/plants13162196.
R.P. Reid et al. (2024):
Microbialite
Accretion and
Growth: Lessons from Shark
Bay and the Bahamas. Open access,
Annu. Rev. Mar. Sci., 16: 487–511.
Note figure 2: The microbialite balancing act, a model for the accretion that
forms the initial architecture of a microbialite.
N.G. Beckman and L.L. Sullivan (2023):
The
Causes and Consequences of Seed Dispersal. Free access,
Annual Review of Ecology, Evolution, and Systematics 54: 403-427.
"... Seed dispersal, or the movement of diaspores away from the parent location, is a multiscale, multipartner process that depends on the interaction of
plant life history with vector movement and the environment
[...] We provide an overview of the
ultimate causes of dispersal and the consequences of this important process
for plant population and community dynamics ..."
Annual Review of Ecology,
Evolution, and Systematics.
The Annual Review of Ecology, Evolution, and Systematics, published since 1970,
covers significant developments
in the fields of ecology, evolutionary biology, and systematics, as they apply to
all life on Earth.
N.J. Tabor and T.S. Myers (2015):
Paleosols
as Indicators of Paleoenvironment and
Paleoclimate. In PDF,
Annual Review of Earth and Planetary Sciences, 43.
See here
as well.
"... Soils form in response to interactions among the lithosphere, hydrosphere, biosphere,
and atmosphere, so paleosols potentially record physical, biological, and chemical
information about past conditions near Earth's surface. As a result,
paleosols are an important resource for terrestrial environmental and climatic reconstructions ..."
G.S. Weissmann et al. (2013):
Prograding
distributive fluvial systems—geomorphic models and ancient examples. In PDF,
SEPM Spec. Publ., 104: 131–48.
See here
as well.
"... Recent work indicates that most modern continental sedimentary basins are
filled primarily by distributive fluvial systems (DFS). In this
article we use depositional environment interpretations observed on Landsat
imagery of DFS to infer the vertical succession of channel and overbank
facies, including paleosols, from a hypothetical prograding DFS ..."
John Southard (2007), MIT Open Learning, Massachusetts Institute of Technology:
!
Sedimentary
Geology.
The course combines aspects of
aspects of modern sediments and ancient sedimentary rocks, textures of siliciclastic
sediments and sedimentary rocks, particle size, particle shape, and particle packing.
Mechanics of sediment transport. Survey of siliciclastic sedimentary rocks: sandstones,
conglomerates, and shales. Carbonate sediments and sedimentary rocks; cherts; evaporites.
Siliciclastic and carbonate diagenesis. Paleontology, with special reference to fossils
in sedimentary rocks. Modern and ancient depositional environments. Stratigraphy.
Sedimentary basins. Fossil fuels: coal, petroleum.
See here
as well.
!
A.J. Hetherington (2024):
Fossil
evidence supports at least two origins of plant roots. PDF file, pp. 3-18, in:
T. Beeckman & A. Eshel (eds.), Plant Roots: The Hidden Half. Fifth edn, CRC Press, Boca Raton.
See likewise
here.
Note figure 1.4: Geological timeline showing major events in early land plant evolution.
!
Figure 1.8, A: Complex rooting system of Asteroxylon mackiei composed of root-bearing axes
and rooting axes. A, Artists reconstruction of A. mackiei in life.
R.A. Gastaldo et al. (2024):
To
rush into the secret house of death: The fate of a Tournaisian plant
Geology, 20.
"... Tournaisian-age failure of marginal lacustrine sediments, and their bulk collapse into an
inland rift-basin lake in the Moncton Subbasin, Canada, led to the entrainment of rare, almost
complete, three-dimensionally preserved non-woody trees. Preservation of these unique fossils
from the Albert Formation was a consequence of contemporaneous seismicity ..."
!
Y. Xing et al. (2016):
Testing
the biases in the rich Cenozoic angiosperm macrofossil record. In PDF,
International Journal of Plant Sciences, 117: 371-388.
DOI: https://doi.org/10.1086/685388.
See likewise here.
"... The data presented here include 2478 assemblages from all Cenozoic epochs and 1961 sites
from all continents, as well as representatives of 221 families (of 445 recognized) and 1859 genera, and show that
the Cenozoic angiosperm macrofossil record is extraordinarily rich.
However, this rich record is temporally,
spatially, and phylogenetically biased: the Miocene is much better sampled than the rest of
Cenozoic, the Northern Hemisphere is better sampled than the Southern Hemisphere ..."
R. Albert (2015): The Petrified Forest of Khorixas (Namibia). In PDf. See likewise here (PDF file, in German).
E.M. Knutsen and D.A. Konovalov (2024):
Accelerating
segmentation of fossil CT scans through Deep Learning. In PDF,
Scientific Reports, 14.
See likewise
here.
!
C. Yu et al. (2024):
Artificial
intelligence in paleontology. Open access,
Earth-Science Reviews, 252.
"... The accumulation of large datasets and increasing data availability have led to the
emergence of data-driven paleontological studies, which reveal an unprecedented picture
of evolutionary history
[...] studies feature a wide range of techniques such as Knowledge-Based Systems (KBS),
neural networks, transfer learning, and many other machine learning methods to automate a
variety of paleontological research workflows ..."
!
H.J.B. Birks et al. (2016):
Does
pollen-assemblage richness reflect floristic richness? A review of
recent developments and future challenges. In PDF,
Review of Palaeobotany and Palynology, 228: 1-25.
See likewise
here.
"... We conclude with an assessment of the current state-of-knowledge about whether pollen richness reflects floristic richness and explore
what is known and unknown in our understanding of pollen–plant richness relationships ..."
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.
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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