Global ETD Search

1	Integration of Analytical Models for Estimating Sediment Supply and Evaluation of Channel Stability Zhou, Hong 04 August 2016 (has links) No description available. Civil Engineering Water Resource Management soil erosion sediment supply Sediment Delivery Ratio SDR channel stability WARSSS Revised Universal Soil Loss Equation RUSLE
2	Stratigraphic implications of the spatial and temporal variability in sediment transport in rivers, deltas and shelf margins Petter, Andrew Lucas, 1980- 29 September 2010 (has links) Sediment delivery to a basin exerts a first-order control over sedimentation, and therefore study of sedimentary rocks can reveal information about the nature of sediment delivery in the past. This dissertation examines several aspects of this problem using experimental, outcrop, and subsurface data. Flume experiments were undertaken to test the combined effects of autogenic alluvial aggradation and forced regression on the development of fluviodeltaic stratigraphy. Alluvial aggradation occurred in response to steady relative sea-level fall, and eventually consumed the entire sediment budget as the river lengthened in response to forced regression. The Campanian Lower Castlegate Sandstone (Utah) was studied as a potential ancient analog resulting from similar autogenic behaviors as observed in the experiments. Extensive measurement of grain-size distributions and paleo-flow depths from outcrop were utilized to explore downstream changes in paleo-hydraulics of the ancient fluvial systems in the Lower Castlegate in response to extensive alluvial aggradation and consequent loss of sediment from transport. An interesting finding was the stratigraphic signature of backwater hydraulic conditions in the distal reaches of the Lower Castlegate paleo-rivers. Finally, a simple and novel inversion scheme was developed for estimating paleo-sediment flux from ancient shelf-margin successions. An advantage of the methodology is that it allows for both spatial and temporal reconstruction of paleo-sediment flux patterns. The inversion scheme was applied to shelf-margin successions in the Washakie-Sand Wash Basin of Wyoming, the New Jersey Atlantic margin, the North Slope of Alaska, and the Zambezi margin of East Africa using published subsurface datasets. The Neogene passive margins within the studied datasets were found to consistently deposit around one-third of their total sediment budget on the shelf-margin topset, and bypass two-thirds of their budget beyond the shelf edge. The implications of this finding on the flux of terrestrial-derived particulate organic carbon (POC) from rivers to the ocean were explored, and a long-term average flux of POC to deepwater storage was estimated. The sediment-flux inversion scheme was also applied to derive input parameters for stratigraphic modeling of the Ebro margin. The modeling results indicate that the autostratigraphic behavior of the margin may have been previously underestimated. / text Sediment flux Sediment supply Shelf margin Clinoform Geometric model Rivers Fluvial Alluvial aggradation Castlegate Stratigraphy
3	Linking Form and Process in Braided Rivers Using Physical and Numerical Models Kasprak, Alan 01 May 2015 (has links) Braided channels arise due to high sediment availability in conjunction with regular competent flows and readily erodible banks. Together, these boundary conditions lead to the deposition and reworking of a network of transient bars that characterize the braided planform. However, quantifying the geomorphic response of braided systems to alterations in these boundary conditions is not straightforward, as channels adjust over a wide range of timescales, rendering traditional field-based observation intractable. As such, the development of simple yet robust relationships between channel morphology and sediment transport has the potential to allow predictions of channel response to altered hydrologic or sediment regimes. In this research, I first use laboratory flume experiments to relate particle travel distance during floods (termed particle path length) and the spacing of channel bars in braided rivers (Chapter 2), finding that deposition sites for sediment in transport can be readily predicted by the characteristic confluence-diffluence spacing in a reach. I then use the relationship between path length and channel morphology to build a simple, open-source morphodynamic model for braided rivers that computes sediment transport using path-length distributions derived from bar spacing (Chapter 3). I explore the validity of this model, specifically noting that its modular framework allows exploration of process representations in morphodynamic modeling in ways existing models do not. Finally, I employ the model to determine the role of sediment supply in braided channel bar morphodynamics (Chapter 4). Specifically, I address the relative roles of sediment sourced from upstream versus sediment sourced from within a braided reach in terms of channel morphodynamics at decadal timescales. This research demonstrates that simple scaling relationships, while necessarily imperfect, nevertheless provide insight into morphodynamic processes in braided rivers, while also allowing predictions of channel response to sediment or hydrologic forcing at the timescales of channel adjustment. braided rivers gravel bed rivers morphodynamics sediment supply sediment transport Environmental Sciences
4	L’évolution géomorphologique des systèmes torrentiels proglaciaires de la vallée de Chamonix-Mont-Blanc, une approche du couplage sédimentaire de la fin du Petit Age Glaciaire au désenglacement récent / Geomorphic evolution of proglacial stream systems of Chamonix- Mont Blanc Valley, sediment connectivity approach from the end of the Little Ice Age to the current glacier retreat Berthet, Johan 21 June 2016 (has links) Depuis la fin du Petit Age Glaciaire, les glaciers du massif du Mont-Blanc se retirent et libèrent ainsi d’importants volumes de sédiments. La fourniture sédimentaire grossière, qui est l’un des éléments de contrôle principaux de l’activité géomorphologique des torrents proglaciaires, peut être profondément modifiée. Dans le contexte de la vallée de Chamonix, où la pression urbaine est très forte, l’accélération du retrait glaciaire soulève des questionnements de la part à la fois des gestionnaires et des scientifiques sur l’évolution des risques et de la gestion des flux solides.L’objectif de ce travail de thèse est d’étudier le couplage sédimentaire entre les espaces libérés des glaces et les torrents jusqu’en fond de vallée, avec un double niveau de réponse. Le premier niveau permet de comprendre les trajectoires géomorphologiques des systèmes glacio-torrentiels depuis la fin du Petit Age Glaciaire et à l’échelle de la vallée. Il est étayé par une analyse géomorphologique et par l’étude de l’évolution du réseau hydrographique, qui s’appuie sur une modélisation et sur de nombreux documents d’archive. Cette étape souligne la diminution du potentiel du système torrentiel à remobiliser des sources sédimentaires. En conséquence, l’activité des torrents a fortement baissée depuis 150 ans. La seconde approche concerne l’étude des dynamiques récentes basée sur la comparaison diachronique de MNT LiDAR à haute résolution. Elle se focalise sur les trois systèmes glacio-torrentiels les plus grands de la vallée (Argentière, Mer de Glace et Bossons) dont les activités morphogènes ont pu être interprétées sous le prisme de crues d’occurrence décennale survenues en août 2014. Cette partie montre l’efficacité des processus de stockage sédimentaire au sein même des espaces désenglacés, ainsi que l’importance du forçage humain sur la morphogénèse torrentielle qui prime désormais sur l’influence du retrait glaciaire. L’état de la fourniture sédimentaire résulte actuellement de l’impact des différentes infrastructures, telles que les captages sous-glaciaires ou l’autoroute d’accès au Tunnel du Mont Blanc.Nos résultats montrent donc une première phase de diminution de l’activité torrentielle, principalement causée par le retrait des glaciers de 1850 à 1950, puis les conséquences pression des activités humaines sur les évolutions hydromorphologiques. La baisse de la torrentialité est toutefois ponctuée de quelques évènements, comme la crue du septembre 1920 sur l’Arveyron de la Mer de Glace, dont nous avons reconstitué les conséquences géomorphologiques. Malgré leur intensité, les effets de ces crues restent néanmoins relativement limités à l’aval immédiat des glaciers.Contrairement donc aux hypothèses initialement soulevées, le retrait glaciaire n’implique pas une augmentation de la fourniture sédimentaire, mais au contraire une diminution des apports du fait de la déconnexion entre les espaces désenglacés et les systèmes torrentiels. / Since the end of Little Ice Age, glaciers of the Mont blanc massif are retreating and large sediment volume are releasing from the ice. Thus, sediment supply, which is a main control factor of the proglacial stream geomorphic activity, could be deeply modified. Therefore, the consequences on the sediment fluxes and the risk management need to be understanding because of the present acceleration of glacier retreat and urban sprawl in the Chamonix valley. The goal of this thesis is to study the sediment coupling between stream systems and areas released by glaciers. A first approach allows understanding the geomorphic trajectory of proglacial system at the Chamonix scale since the end of the Little Ice Age. Our results supported by modelling and archives analyses, show the decreasing capacity of the hydrographic pattern to be connected with sediment sources. The second approach is lead on the LiDAR DEM multi-temporal comparison. It focuses on the three main proglacial systems: Argentière, Mer de Glace and Bossons, whom occurred a decennal flood during the 2014 summer. This part of our study underlines the storage efficiency into deglaciated areas and the increasing role of anthropic forcing. Present sediment yield to proglacial stream is leaded by facilities such as the Mont Blanc Tunnel substructure or the subglacial harnessing. Our results show that the decreasing geomorphic activity of proglacial stream in the Chamonix valley is mainly caused by glacier retreat from the early 18th Century to the middle 20th century, then it is leaded by the increasing human pressure. Nevertheless, the fall of stream activity is punctuated by extreme events, such as the 1920 flood in the Arveyron of the Mer de Glace that we reconstructed the geomorphic consequences. Despite their intensity, effects of that king of events are limited close to the glacier downstream. Contrary to our initial hypotheses, glacier retreat in the Chamonix Valley, is not follow by a geomorphic crisis of proglacial streams because of the disconnectivity between sediment released from the ice and stream systems. Torrent proglaciaire Retrait glaciaire Fourniture sédimentaire Connectivité sédimentaire Proglacial stream Glacier retreat Sediment supply Sediment connectivity 551.3
5	Stratigraphic Architecture, Depositional Processes and Reservoir Implications of the Basin Floor to Slope Transition, Neoproterozoic Windermere Turbidite System, Canada Navarro Ugueto, Lilian Leomer January 2016 (has links) Deep-water strata of the Neoproterozoic Kaza Group and Isaac Formation (Cariboo Group) in the southern Canadian Cordillera (B.C.) were deposited in a passive-margin basin during the break-up of supercontinent Rodinia. At the Castle Creek and Mount Quanstrom study areas, a remarkably continuous stratigraphic interval throughout these units preserves a record of basin-floor overlain by strata deposited in the lowermost part of the slope. Although similar stratal intervals have been described from ancient and modern deep-marine settings, they still remain poorly understood. Three main stratal units are recognized within the study areas. The lower unit consists of three channel-lobe systems formed in the basin floor to slope transition. Uniquely, siliciclastic-dominated strata here consist of a variety of small- and few large-scale scour elements, indicating transport bypass along the channel-lobe transition zone, in addition to detached or attached depositional lobes composed mostly of distributary channels, fine-grained deposits, and uncommon splays, and a rare slope leveed channel complex. The middle unit is a siliciclastic-dominated succession of stacked, km-scale mass-transport deposits (i.e. debrites and slides), which indicates the more frequent emplacement of increasingly larger mass failures on a prograding slope, and are overlain by fine-grained, splay deposits that are successively overlain by channel, ponded and fine-grained deposits. In contrast, the upper unit is a mixed siliciclastic-carbonate slope succession of the first Isaac carbonate, a regional marker horizon that comprises mostly carbonate-rich and siliciclastic-rich fine-grained strata intercalated with channel and gully complexes that are mostly filled with coarser-grained strata. Abrupt changes in facies trends, stratal stacking patterns and depositional styles throughout these units are largely linked to long-term changes in relative sea level and its control on sediment supply, namely sediment caliber, volume and mineralogy. Notably, in the upper unit, small-scale changes in sediment source and supply are related to shorter sea-level variations superimposed on the long-term eustatic change. Slope-basin floor transition Channel-lobe transition zone Windermere turbidite system First Isaac Carbonate Architecture Deep-marine setting sediment supply long-term depositional controls
6	Reconstructing environmental forcings on aeolian dune fields : results from modern, ancient, and numerically-simulated dunes Eastwood, Erin Nancy. 08 September 2014 (has links) This dissertation combines studies of aeolian bedforms and aeolian dune-field patterns to create a comprehensive set of tools that can be used in tandem (or separately) to extract information about climate change and landscape evolution, and to identify the controls on formation for specific modern dune fields or ancient aeolian sequences. The spatial distribution of surface processes, erosion/deposition rates, and lee face sorting on aeolian dunes are each a function of the incident angle. This correlation between stratification style and incidence angle can be used to develop a “toolbox” of methods based on measurements of key suites of parameters found in ancient aeolian deposits. Information obtained from the rock record can be used as input data for different kinds of numerical models. Regional-scale paleowind conditions can be used to validate paleoclimate and global circulation models. Understanding the natural variability in the Earth’s climate throughout its history can help predict future climate change. Reconstructed wind regimes and bedform morphologies can be used in numerical models of aeolian dune-field pattern evolution to simulate patterns analogous to those reconstructed from ancient aeolian systems. Much of the diversity of aeolian dune-field patterns seen in the real world is a function of the sediment supply and transport capacity, which in turn determine the sediment availability of the system. Knowledge of the sediment supply, availability, and transport capacity of aeolian systems can be used to predict the amount of sand in the system and where it might have migrated. This information can be extremely useful for development and production of oil and gas accumulations, where a discovery has been made but the spatial extent of the aeolian reservoir is unknown. / text Aeolian Sediment transport Dune-field evolution Dune-field development Paleoclimate reconstructions White Sands Dune Field, NM Permian Cedar Mesa Sandstone, Utah Numerical modeling Sediment supply Transport capacity Dune-field patterns Clustered bedforms Superimposed bedforms Climate change Landscape evolution Wind regimes
7	Contraintes et potentialités naturelles de quelques sites portuaires antiques de Méditerranée et de mer Noire (Fréjus, Ampurias, Kition, Istanbul, Orgamé) / Natural Constraints and potentials of some ancient harbours in the Mediterranean and Black Sea (Frejus, Ampurias, Kition, Istanbul, Orgame) Bony, Guénaëlle 04 July 2013 (has links) Il y a 7000 ans BP, la stabilisation du niveau marin a entraîné la formation de deltas. Ces zones deltaïques abritent des milieux aux degrés de protection différents favorables à une activité maritime. Cependant, ces espaces sont soumis à des contraintes naturelles : à l'échelle de la longue durée, l'alluvionnement des deltas entraîne la mobilité des littoraux et le colmatage des milieux portuaires ; à l'échelle de l'événement, les tempêtes, les tsunamis et la mobilité crustale entraînent la destruction, la submersion ou le soulèvement des zones portuaires. Ce travail porte sur l'étude des contraintes et des potentialités environnementales de cinq ports antiques répartis dans le monde Méditerranéen en marge de deltas. L'objectif est d'estimer le poids de ces contraintes sur les sociétés via une approche statistique. Pour quatre des sites d'études, l'alluvionnement est le forçage majeur. A Kition et Orgame, l'impact de l'alluvionnement est indirect. La fermeture des baies marines par l'édification de cordons littoraux crée des environnements lagunaires propices à l'installation de zones portuaires. En revanche, Fréjus et Ampurias sont soumis à un alluvionnement direct qui a rapidement colmaté les bassins. A partir de l'époque romaine et avec l'invention de la pouzzolane, des zones portuaires sont installées en milieu littoral ouvert, comme à Istanbul. Dans un contexte tectoniquement actif, les tsunamis constituent la contrainte majeure opérant sur le port byzantin de Théodose à Istanbul. Un dépôt grossier et chaotique, contenant du matériel marin et archéologique remanié, compose une partie de la séquence stratigraphique de colmatage du bassin et témoigne de ce forçage. / The stabilization of sea level at 7000 years ago led to the formation of deltaic areas. These areas constituted sheltered environments particularly conducive to maritime activity. However, these areas were also subject to natural constraints for human occupation: at long timescales, high sediment supply to deltaic areas led to significative coastal changes and the infilling of harbour areas; at shorter timescales, high-energy events and crustal mobility led to the destruction, submersion and/or uplift of harbour areas. This work focuses on the study of environmental constraints and potentialities governing five ancient harbours, located on deltaic margins in the Mediterranean. The study aims to semi-qualitatively measure of the weight of these constraints on harbour cities, using statistical approach. High sediment supply is the major natural forcing. At Orgame and Kition, the closure of marine bays by coastal barriers led to the formation of lagoon environments conducive to the installation of harbour areas. Frejus and Ampurias were subject to direct siltation which quickly infilled the harbour basin. The invention of the pozzolan in Roman times means that harbours could be constructed in coastal areas open to the sea and away from river mouths, such as Istanbul harbour. In a tectonically active context, tsunamis are the major constraint acting in the Byzantine harbour of Theodosius in Istanbul. There, the stratigraphic sequence contains a coarse and chaotic deposit composed of reworked marine and archaeological material which demonstrates the societal impacts of such a natural and destructive forcing agent. Géoarchéologie Port antique Fréjus Ampurias Orgame Kition Yenikapi Risque naturel Delta Alluvionnement Tsunami Sédimentologie Ostracode Statistique Geoarcheology Ancient harbour Frejus Ampurias Orgame Kition Yenikapi Natural hazard Delta Sediment supply Tsunami Sedimentology Ostracoda Statistical analysis
8	The influence of biophysical feedbacks and species interactions on grass invasions and coastal dune morphology in the Pacific Northwest, USA Zarnetske, Phoebe Lehmann, 1979- 09 September 2011 (has links) Biological invasions provide a unique opportunity to study the mechanisms that regulate community composition and ecosystem function. Invasive species that are also ecosystem engineers can substantially alter physical features in an environment, and this can lead to cascading effects on the biological community. Aquatic-terrestrial interface ecosystems are excellent systems to study the interactions among invasive ecosystem engineers, physical features, and biological communities, because interactions among vegetation, sediment, and fluids within biophysical feedbacks create and modify distinct physical features. Further, these systems provide important ecosystem services including coastal protection afforded by their natural features. In this dissertation, I investigate the interactions and feedbacks among sand-binding beach grass species (a native, Elymus mollis (Trin.), and two non-natives, Ammophila arenaria (L.) Link and A. breviligulata Fernald), sediment supply, and dune shape along the U.S. Pacific Northwest coast. Dunes dominated by A. arenaria tend to be taller and narrower compared to the shorter, wider dunes dominated by A. breviligulata. These patterns suggest an ecological control on dune shape, and thus, coastal vulnerability to overtopping waves. I investigate the causes and consequences of these patterns with experiments, field observations, and modeling. Specifically, I investigate the relative roles of vegetation and sediment supply in shaping coastal dunes over inter-annual and multi-decadal time scales (Chapter 2), characterize a biophysical feedback between beach grass species growth habit and sediment supply (Chapter 3), uncover the mechanisms leading to beach grass coexistence and whether A. breviligulata can invade and dominate new sections of coastline (Chapter 4), and examine the non-target effects resulting from management actions that remove Ammophila for the recovery of the threatened Western Snowy plover (Charadrius alexandrinus nivosus) (Chapter 5). I found that vegetation and sediment supply play important roles in dune shape changes across inter-annual and multi-decadal time scales (Chapter 2). I determined that a biophysical feedback between the beach grass growth habits and sediment supply results in species-specific differences in sand capture ability, and thus, is a likely explanation for differences in dune shape (Chapter 3). I found that all three beach grass species can coexist across different sediment deposition rates, and that this coexistence is largely mediated by positive direct and indirect species interactions. I further determined that A. breviligulata is capable of invading and dominating the beach grass community in regions where it is currently absent (Chapter 4). Combined, these findings indicate that A. breviligulata is an inferior dune building species as compared to A. arenaria, and suggest that in combination with sediment supply gradients, these species differences ultimately lead to differences in dune shape. Potential further invasions of A. breviligulata into southern regions of the Pacific Northwest may diminish the coastal protection ability of dunes currently dominated by A. arenaria, but this effect could be moderated by the predicted near co-dominance of A. arenaria in these lower sediment supply conditions. Finally, I found that the techniques used to remove Ammophila for plover recovery have unintended consequences for the native and endemic dune plant communities, and disrupt the natural disturbance regime of shifting sand. A whole-ecosystem restoration focus would be an improvement over the target-species approach, as it would promote the return of the natural disturbance regime, which in turn, would help recover the native biological community. The findings from this dissertation research provide a robust knowledge base that can guide further investigations of biological and physical changes to the coastal dunes, can help improve the management of dune ecosystem services and the restoration of native communities, and can help anticipate the impacts of future beach grass invasions and climate change induced changes to the coast. / Graduation date: 2012 / Access restricted to the OSU Community at author's request from Sept. 22, 2011 - March 22, 2012 ecosystem engineer invasive species coastal dune foredune wind tunnel species interactions Ammophila arenaria Ammophila breviligulata Elymus mollis beach grass Charadrius alexandrinus nivosus targeted management Oregon Washington ecosystem service coastal protection sediment supply Lotka-Volterra facilitation coexistence indirect effects sand supply species distributions sediment transport Elymus -- Ecology -- Northwest, Pacific Sand dunes -- Northwest, Pacific Sand dune ecology -- Northwest, Pacific Grasses -- Ecology -- Northwest, Pacific

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