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Sedimentology and Taphonomy of the <em>Abydosaurus mcintoshi</em> Quarry, (Naturita Formation, Early Cretaceous, Latest Albian), Dinosaur National Monument, UtahHolmes, Aaron Daniel 01 June 2017 (has links)
The holotypic locality of the brachiosaurid titanosauriform sauropod, Abydosaurus mcintoshi, is quarry DNM-16, located in Dinosaur National Monument. The bones are preserved near the base of a heterolithic, trough cross stratified to planar bedded sandstone channel complex. The trough cross to planar bedded sandstones mark times of variable flow with times of high flow velocity based on bones whose upper surfaces were eroded before final burial. The abundance of mud with the dominant medium to fine sand, and poorly confined sandstone channels indicate the bones were transported and buried in medial to distal intermittent flows of a distributive fluvial system. The quarry is at the base of the Naturita Formation, the base of which is latest Albian in age. The sauropods lived and died in the middle Cretaceous as the Cretaceous seaway advanced southward. The unconformity below the Naturita Formation and on top of the underlying the Ruby Ranch Member represents the LK-2 sequence boundary. The quarry produced ~260 bones, all of which represent Abydosaurus, except for several small theropod teeth, denoting a single catastrophic event acting on a group of sauropods. About one-third of the bones occur in close association or articulation, including three skulls (one articulated with the first five cervical vertebrae), five limbs, and strings of caudal vertebrae. There is no evidence of preburial weathering or breakage, and trample scratch marks are rare. More than 20% of the bones exhibit irregular, mm-scale pits occur on the shafts and the articular ends of limb bones are commonly hollowed out. The irregular pits are termite foraging traces, and hollows indicate extensive mining by these insects. At least seven individuals of Abydosaurus are present, representing at least two ontogenetic stages (juveniles and subadults).Together, these observations indicate the following: (1) the catastrophic death of a sauropod herd; (2) partial carcass maceration; (3) minor transportation, including articulated units (skulls, vertebrae, limbs); (4) rapid burial in migrating, ephemeral, branches of a distributary fluvial system; (5) channel migration resulting in in-situ scouring of the upper surface of some bones; (6) burial of scoured bones. Termite infestation occurred both prior to, and after, fluvial entrainment and burial.
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Paleopedology and fluvial sedimentology of the Upper Devonian Catskill Formation, Central Pennsylvania: A test of the distributive fluvial systemOest, Christopher January 2015 (has links)
The Upper Devonian Catskill Formation represents marginal marine and alluvial sediments which prograded into the Appalachian Basin during the Acadian Orogeny. Distributive fluvial systems (DFS) are prevalent in modern actively aggrading basins in all tectonic and climatic regimes and may be common in the rock record. In this study, I reinterpret the Catskill Formation as a prograding distributive fluvial system (DFS) on the basis of up-section variability in paleosols, channel sandstone textural trends, and alluvial architecture. At least three distinct pedotypes representative of prevailing soil forming conditions are identified during deposition of the Irish Valley, Sherman Creek, and Duncannon Members of the Catskill Formation. Increased paleosol drainage is inferred from an up-section transition from hydromorphic aqualfs within the Irish Valley Member to non-calcareous, uderts within the Duncannon Member. Qualitative field observations of channel sandstone morphology show an increase in channel size up-section. Channels occur as small isolated bodies at the base of the section, transitioning to relatively larger, amalgamated channels, and finally, large isolated channel bodies up-section. Sandstones are litharenites and coarsen-upward throughout the Catskill Formation overall. This coarsening upward trend results from increasing paleo-flow competency in larger channels up-section. These results are consistent with deposition of the Catskill Formation by DFS processes and demonstrate the utility of paleopedological analysis in interpreting alluvial depositional processes. Identifying DFS in the rock record has implications for paleosol-based paleoclimatic studies, as paleosols forming on prograding DFS have increased paleosol drainage up-section, which could potentially be misinterpreted as a shift from prevailing humid to arid paleoclimatic conditions. Recognition of DFS in the rock record also has implications for basin analysis and exploration of fluvial aquifers and hydrocarbon reservoirs, as the stratigraphic architecture of DFS are fundamentally different from tributary systems at the basin scale. / Geology
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Controls on river and overbank processes in an aggradation-dominated system : Permo-Triassic Beaufort Group, South AfricaGulliford, Alice Rachel January 2014 (has links)
The Permo-Triassic lower Beaufort Group fluvial deposits extend over 100s of kilometres within the Karoo Basin, South Africa. A detailed study of the depositional architecture and stacking patterns of sand bodies within a 900 m thick succession has enabled interpretation of the controls on ancient river channel and overbank processes. Facies include very fine- to medium-grained sandstone, intra-formational conglomerate, mudstone and palaeosols. Channel-belts are dominated by upper flow regime structures, consistent with a flashy to ephemeral fluvial system. The overbank deposits comprise splays interbedded with purple, green and grey mudstone; these floodplain colour changes signify water table fluctuations. A hierarchy of channel-related elements has been established that recognises beds, bedsets, storeys, channel-belts, complexes and complex sets. Each channel-belt may be single- or multi-storey, whereby one storey represents the complete cut and fill cycle of a single migrating river, comprising bar accretion elements and channel-abandonment fill. The abandonment fill elements often consist of heterolithic plugs of climbing ripple-laminated very fine-grained sandstone, or interbedded claystone with siltstone. The Beaufort channel-belts preserve either lateral- or downstream-accretion patterns, or a combination. Each belt has either a lenticular or tabular geometry, recognisable by an erosional base overlain by intra-formational conglomerate lag and barform deposits. Genetically related channel-belts cluster to form complexes, of which two broad styles have been identified: Type A) laterally and vertically stacked channel-belts, and Type B) sub-vertically stacked channel-belts. There is evidence of localised clustering of sub-vertically stacked channel-belts adjacent to extensive overbank mudstone deposits. The apparent lack of a well-defined ‘container’ surface with mappable margins, suggests that this stacked channel-belt architecture represents an avulsion complex rather than a palaeovalley-fill. The lateral and stratigraphic variability in fluvial-overbank architecture is interpreted as the interplay of several controls. Allogenic forcing factors include, tectonic subsidence that influences accommodation, sediment supply, and high frequency climate cycles associated with the flashy discharge regime and expressed in the mudrock colour changes and distribution of palaeosols. The depositional river style, variability in channel-belt stacking patterns and compensational stacking of some channel-belt/splay complexes is interpreted to be the result of autogenic channel avulsion, supported by an absence of significant erosion. The relative merits of basin-axial trunk river and distributive fluvial system (DFS) models are assessed from detailed architectural and stratigraphic outcrop studies.
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