Browsing by Author "Schiffbauer, James Daniel"

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    Contributions and New Methods in Paleontology: Geochemical, Ultrastructural, and Microstructural Characterization of Archean, Proterozoic, and Phanerozoic Fossils
    Schiffbauer, James Daniel (Virginia Tech, 2009-05-01)
    Over the past decade, the study of organismal or systematic paleobiology has been progressing into a new age of digital paleobiology, in which advanced instrumentation is utilized for primary data collection and analyses. Having been progressing throughout this field of study, advanced instruments–commonly electron- and ion- microbeam equipment–have been employed for numerous fossils over the entire range of geologic time, from microfossils to macrofossils and from the Archean (beginning at 3800 Ma) to the Cenozoic (ending at the recent). These techniques, predominantly used for geochemical, morphological, and ultra-/micro-structural analyses, have unlocked an incredible amount of detail contributing to our understanding of fossil organisms, their modes of life, and their biological affinities. But further, as these techniques continue to grow and become popularized in various fields of paleobiological study, they are certain to significantly progress our comprehension and knowledge of the evolution of life through time. While the chapters presented in this dissertation may not have a unifying theme in terms of a distinct fossil organism or specific time in Earth's history, furthering the use of electron- and ion- microbeam instrumentation and expanding the paleo-genres to which digital paleobiological approaches may be applied encompasses the fundamental intention of my research. Two of the chapters reported here focus on the geochemical, ultrastructural, and microstructural investigation of organic-walled microfossils, or acritarchs, from the Paleoproterozoic (2500–1600 Ma) and Mesoproterozoic (1600–1000 Ma), using a range of advanced instrumentation including field emission scanning electron microscopy, transmission electron microscopy, laser Raman spectroscopy, electron microprobe, secondary ion mass spectroscopy, and focused ion beam electron microscopy. Moving into the Neoproterozoic (1000–542 Ma), the third primary research chapter utilizes field emission scanning electron microscopy for high-resolution, high magnification imaging and quantitative evaluation of an entire fossil assemblage–from acritarchs and algal fossils to the earliest metazoan embryos. This study was conducted in an effort to examine and describe the phosphatization taphonomic window of the Doushantuo Formation of South China, which is a prime example of exceptional preservation. Finally, the fourth primary research chapter reported here uses field emission scanning electron microscopy and environmental scanning electron microscopy in a field of paleobiology in which advanced instrumentation has been highly underutilized – predatory-prey interactions. This research examines microstructural characteristics of predatory drill holes in both modern and fossil organisms in an attempt to mitigate the identification of predation traces in the fossil record.
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    Contributions to late Ediacaran geobiology in South China and southern Namibia
    Meyer, Michael B. (Virginia Tech, 2013-06-11)
    The Ediacaran, particularly the late Ediacaran-Cambrian (E-") boundary (551-541 Ma), has been noted as a major time of biological and biochemical transition, including: the rise of predators, the emergence of skeletons, the radiation of bioturbators, and large fluctuations in oceanic chemical conditions (e.g. anoxia/euxinia/ferruginia) with emerging data  suggesting that it is not until the late Ediacaran Period (551-542 Ma) when pervasive oxidation of the deep oceans occurred. In addition, the study of Ediacaran paleobiology involves numerous factors, including but not limited to, restricted amount of outcrops, taphonomic biases, metamorphism, enigmatic phylogenetic affinities, non-actualistic atmospheric and oceanic conditions, and unusual taphonomic windows, making it difficult to assign order to the myriad types of fossils (both body and trace) found during this time . It is with these problems in mind that my dissertation focuses on taphonomic questions in the late Ediacaran. We observe fossil through the taphonomic window and thereby colors all aspects of the study of that organism. By understanding how an organism was preserved we can learn about other factors affecting it, such as their taxonomic affinities, paleoecology, and morphology. All of these factors were examined through taphonomic investigations and this can be seen in the analytical path through my chapters. In chapter two I examined the preservation of trace fossils in the late Ediacaran. In chapter three I analyzed the taphonomy of an exceptionally preserved Ediacaran fossil to solve its affinity, tubular trace or tubular soft-bodied fossil. In chapter four, understanding the nature of exceptional preservation, I investigated the taphonomy of an Ediacara fossil in coarse grained sediments. In chapter five, I combined the findings of the previous chapters and applied that knowledge to analyze the in situ three dimensional morphology of an Ediacara fossil. Each of the projects presented pairs new technologic methodologies (SEM, BSE-Z, EDS, Raman, microCT) with traditional paleontological and petrologic investigations (field work, hand sample, and petrographic thin-section analysis). The result of this union of Old and New are findings that expand our understanding of these earliest multicellular organisms, their modes of life, and their biological affinities.
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    Paleobiology of the Early Cambrian Yanjiahe Formation in Hubei Province of South China
    Broce, Jesse (Virginia Tech, 2013-05-23)
    Fossils recovered from limestones of the lower Cambrian (Stage 2-3) Yanjiahe Formation in Hubei Province, South China, recovered using acetic acid maceration, fracturing, and thin sectioning techniques were examined using a combination of analytical techniques, including energy dispersive spectroscopic (EDS) elemental mapping and micro-focus X-ray computed tomography (micro-CT). One important fossil recovered and analyzed with these techniques is a fossilized embryo. Fossilized animal embryos from lower Cambrian rocks provide a rare opportunity to study the ontogeny and developmental biology of early animals during the Cambrian explosion. The fossil embryos in this study exhibit a phosphatized outer envelope (interpreted as the chorion) that encloses a multicelled blastula-like embryo or a calcitized embryo marked by sets of grooves on its surface. The arrangement of these grooves resembles annulations found on the surface of the Cambrian-Ordovician fossil embryo Markuelia. Previously described late-stage Markuelia embryos exhibit annulations and an introvert ornamented by scalids, suggesting a scalidophoran affinity. In the Yanjiahe fossils illustrated herein, however, the phosphatized chorions and blastulas are not taxonomically or phylogenetically diagnostic, and the late-stage embryo is secondarily calcitized and thus poorly preserved, with only vague grooves indicative of Markuelia-type annulations. Consequently, their taxonomic assignment to the genus Markuelia is uncertain. If they indeed belong to the genus Markuelia, they are the oldest known Markuelia fossils from China, and represent both a new occurrence and possibly a new species.