Global ETD Search

1	Modelling oxygen isotopes in the UVic Earth System Climate Model under preindustrial and Last Glacial Maximum conditions: impact of glacial-interglacial sea ice variability on seawater d18O Brennan, Catherine Elizabeth 10 September 2012 (has links) Implementing oxygen isotopes (H218O, H216O) in coupled climate models provides both an important test of the individual model's hydrological cycle, and a powerful tool to mechanistically explore past climate changes while producing results directly comparable to isotope proxy records. The addition of oxygen isotopes in the University of Victoria Earth System Climate Model (UVic ESCM) is described. Equilibrium simulations are performed for preindustrial and Last Glacial Maximum (LGM) conditions. The oxygen isotope content in the model's preindustrial climate is compared against observations for precipitation and seawater. The distribution of oxygen isotopes during the LGM is compared against available paleo-reconstructions. Records of temporal variability in the oxygen isotopic composition of biogenic carbonates from ocean sediment cores inform our understanding of past continental ice volume and ocean temperatures. Interpretation of biogenic carbonate d18O variability typically neglects changes due to factors other than ice volume and temperature, equivalent to assuming constant local seawater isotopic composition. This investigation focuses on whether sea ice, which fractionates seawater during its formation, could shift the isotopic value of seawater during distinct climates. Glacial and interglacial states are simulated with the isotope-enabled UVic ESCM, and a global analysis is performed. Results indicate that interglacial-glacial sea ice variability produces as much as a 0.13 permil shift in local seawater, which corresponds to a potential error in local paleotemperature reconstruction of approximately 0.5 C. Isotopic shifts due to sea ice variability are concentrated in the Northern Hemisphere, specifically in the Labrador Sea and northeastern North Atlantic. / Graduate oxygen isotopes sea ice glacial interglacial preindustrial Last Glacial Maximum
2	¹⁰Be cosmogenic exposure ages of late pleistocene moraines near the Maryburn Gap of the Pukani Basin, New Zealand / Doughty, Alice Marie, January 2008 (has links) Thesis (M.S.) in Earth Sciences--University of Maine, 2008. / Includes vita. Includes bibliographical references (leaves 79-88).
3	The effect of lower sea level on geostrophic transport through the Florida Straits during the last glacial maximum Ionita, Dana 14 January 2009 (has links) We investigate the effect of a 120 meter sea level drop on transport through the Caribbean Sea and the Florida Straits during the Last Glacial Maximum (LGM) relative to the present, using the Regional Ocean Modeling System (ROMS). A geostrophic transport estimate for the Florida Straits suggests the LGM Florida Current was weaker than today by one third, inferring a likely decrease in the North Atlantic overturning circulation by 12-15 Sv. A possible impact of a shallower LGM Florida Straits sill depth on the Florida Current has been suggested. Our model results show that the volume transport through the Florida Straits is slightly reduced in a lower sea level model simulation when compared to a control sea level simulation (34.8 ± 2.0 Sv vs. 39.8 ± 2.3 Sv). The difference in transport is of the order of 5 Sv, representing a maximum limit to the LGM flow reduction due to sea level change. Therefore the change in sill depth between the LGM and the present is unlikely to have been a cause of the entire observed flow reduction. Geostrophic transport Florida Straits LGM Last Glacial Maximum Sea level Geostrophic currents Last Glacial Maximum Florida, Straits of
4	Paleo-proxies for the thermocline and lysocline over the last glacial cycle in the Western Tropical Pacific Leech, Peter Joseph 20 September 2013 (has links) The shape of the thermocline and the depth of the lysoline in the western tropical Pacific are both influenced by the overlying atmosphere, and both the shape of thermocline and the depth of the lysocline can be reconstructed from foraminifera-based paleo-proxies. Paleoclimate proxy evidence suggests a southward shift of the Intertropical Convergence Zone (ITCZ) during times of Northern Hemisphere cooling, including the Last Glacial Maximum (LGM), 19-23 ka before present. However, evidence for movement over the Pacific has mainly been limited to precipitation reconstructions near the continents, and the position of the Pacific marine ITCZ is less well constrained. In this study, I address this problem by taking advantage of the fact that the upper ocean density structure reflects the overlying wind field. I reconstruct changes in the upper ocean density structure during the LGM using oxygen isotope measurements on the planktonic foraminifera G. ruber and G. tumida in a transect of sediment cores from the Western Tropical Pacific. The data suggest a ridge in the thermocline just north of the present-day ITCZ persists for at least part of the LGM, and a structure in the Southern Hemisphere that differs from today. The reconstructed structure is consistent with that produced in a General Circulation Model with both a Northern and Southern Hemisphere ITCZ. I also attempt to reconstruct the upper ocean density structure for Marine Isotope Stages 5e and 6, the interglacial and glacial periods, respectively, previous to the LGM. The data show a Northern Hemisphere thermocline ridge for both of these periods. There is insufficient data to draw any conclusions about the Southern Hemisphere thermocline. Using the same set of sediment cores, I also attempt to reconstruct lysocline depth over the last 23,000 years using benthic foraminiferal carbon isotope ratios, planktonic foraminiferal masses, and sediment coarse fraction percentage. Paleoclimate proxy evidence and modeling studies suggest that the deglaciation following the LGM is associated with a deepening of the lysocline and an increase in sedimentary calcite preservation. Although my data lack the resolution to constrain the depth of the lysocline, they do show an increase in calcite preservation during the last deglaciation, consistent with lysocline deepening as carbon moves from the deep ocean to the atmosphere. Western Tropical Pacific Thermocline Lysocline Intertropical convergence zone Last glacial maximum Foraminifera Oxygen isotopes Ocean-atmosphere interaction Thermoclines (Oceanography) Marine meteorology Last Glacial Maximum
5	Asian monsoon over mainland Southeast Asia in the past 25 000 years Chabangborn, Akkaneewut January 2014 (has links) The objective of this research is to interpret high-resolution palaeo-proxy data sets to understand the Asian summer monsoon variability in the past. This was done by synthesizing published palaeo-records from the Asian monsoon region, model simulation comparisons, and analysing new lake sedimentary records from northeast Thailand. Palaeo-records and climate modeling indicate a strengthened summer monsoon over Mainland Southeast Asia during the Last Glacial Maximum (LGM), compared to dry conditions in other parts of the Asian monsoon region. This can be explained by the LGM sea level low stand, which exposed Sundaland and created a large land-sea thermal contrast. Sea level rise ~19 600 years before present (BP), reorganized the atmospheric circulation in the Pacific Ocean and weakened the summer monsoon between 20 000 and 19 000 years BP. Both the Mainland Southeast Asia and the East Asian monsoon hydroclimatic records point to an earlier Holocene onset of strengthened summer monsoon, compared to the Indian Ocean monsoon. The asynchronous evolution of the summer monsoon and a time lag of 1500 years between the East Asian and the Indian Ocean monsoon can be explained by the palaeogeography of Mainland Southeast Asia, which acted as a land bridge for the movement of the Intertropical Convergence Zone. The palaeo-proxy records from Lake Kumphawapi compare well to the other data sets and suggest a strengthened summer monsoon between 10 000 and 7000 years BP and a weakening of the summer monsoon thereafter. The data from Lake Pa Kho provides a picture of summer monsoon variability over 2000 years. A strengthened summer monsoon prevailed between BC 170-AD 370, AD 800-960 and since AD 1450, and was weaker about AD 370-800 and AD 1300-1450. The movement of the mean position of the Intertropical Convergence Zone explains shifts in summer monsoon intensity, but weakening of the summer monsoon between 960 and 1450 AD could be affected by changes in the Walker circulation. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript..</p> Asian monsoon ITCZ palaeo-vegetation palaeoclimate lake sediment Last Glacial Maximum Holocene
6	Southern African Climate Dynamics and Archaeology during the Last Glacial Maximum Phillips, Anna 09 December 2013 (has links) There is little consensus on what forced the climate of southern Africa to change during the Last Glacial Maximum (LGM). Because of southern Africa's latitudinal position, changes in seasonal precipitation can help resolve the influence of internal climate factors such as groundwater and external climate forcers such as large scale atmospheric circulation patterns. This paper presents a simple model of groundwater discharge based on permeability and topography in comparison with general circulation model precipitation results and paleoenvironmental proxy records. Results show that during the LGM the Intertropical Convergence Zone (ITCZ) likely weakened and moved slightly further south while the westerlies likely expanded slightly northward, with no significant change in strength. The climate and groundwater results were compared to the distribution of LGM and pre-LGM archaeological sites. Results show that the Later Stone Age peoples of southern Africa were likely inhabiting a relatively wet environment rather than an arid one. South Africa paleohydrology atmospheric circulation Last Glacial Maximum archaeology 0426 0725
7	Southern African Climate Dynamics and Archaeology during the Last Glacial Maximum Phillips, Anna 09 December 2013 (has links) There is little consensus on what forced the climate of southern Africa to change during the Last Glacial Maximum (LGM). Because of southern Africa's latitudinal position, changes in seasonal precipitation can help resolve the influence of internal climate factors such as groundwater and external climate forcers such as large scale atmospheric circulation patterns. This paper presents a simple model of groundwater discharge based on permeability and topography in comparison with general circulation model precipitation results and paleoenvironmental proxy records. Results show that during the LGM the Intertropical Convergence Zone (ITCZ) likely weakened and moved slightly further south while the westerlies likely expanded slightly northward, with no significant change in strength. The climate and groundwater results were compared to the distribution of LGM and pre-LGM archaeological sites. Results show that the Later Stone Age peoples of southern Africa were likely inhabiting a relatively wet environment rather than an arid one. South Africa paleohydrology atmospheric circulation Last Glacial Maximum archaeology 0426 0725
8	Reconstitution de la fréquence des écroulements rocheux post-LGM dans le Massif du Mont-Blanc / Reconstruction of the frequency of rockfalls and rock avalanchesin the Mont Blanc massif since the Last Glacial Maximum Gallach, Xavi 12 October 2018 (has links) La haute montagne est un terrain particulièrement sensible aux variations climatiques. La hausse de température depuis plusieurs décennies a un fort impact sur les parois du massif du Mont Blanc : la dégradation du permafrost s’y traduit par une activité gravitaire majeure. Une augmentation du nombre d'écroulements (>100 m3) liés à des périodes chaudes a en effet été mis en évidence à plusieurs échelles de temps, lors des étés particulièrement chauds de 2003 et 2015 comme au cours des trois dernières décennies. La fréquence des écroulements dans le massif devrait continuer à s’accroitre avec l’augmentation de la température au 21e siècle.En revanche, la fréquence des écroulements dans le massif antérieurement à la fin du Petit Âge Glaciaire (PAG) est très largement inconnue. Pendant l'Holocène voire le Tardiglaciaire, les écroulements dans le massif du Mont Blanc ont-ils également été favorisés par les hausses de température ? Pour répondre à cette question, cette thèse poursuit quatre objectifs :i. Dater un grand nombre d'écroulements dans la partie centrale du massif pour comprendre leur distribution pendant l'Holocène et le Tardiglaciaire. L'âge des niches d’arrachement est obtenu par datation cosmogénique.ii. Vérifier les possibles corrélations entre périodes à forte occurrence d’écroulements et périodes climatiques post-glaciaires.iii. Quantifier le volume des écroulements par reconstruction 3D de la forme des blocs écroulés, et étudier la relation entre volumes écroulés et périodes climatiques.iv. Etudier la relation entre âge d'exposition et couleur des niches d’arrachement quantifiée avec la spectroscopie de réflectance.Un total de 70 surfaces a été échantillonné dans les parois du massif au cours de trois campagnes de terrain en 2006, 2011, et 2015-2016. Les âges d'exposition de 63 surfaces ont été obtenus, compris entre 30 ± 20 ans et 100.50 ± 8.50 ka. Trois groupes d’âges peuvent être corrélés aux périodes climatiques chaudes que sont : les Périodes Chaudes de l'Holocène moyen (7.50 – 5.70 ka), l'Optimum de l'âge de Bronze (3.35 – 2.80 ka) et le Période Chaude Romaine (2.35 – 1.75 ka) ; un quatrième groupe d'âges est daté entre 4.91 et 4.32 ka. Le groupe d'âges le plus nombreux, entre 1.09 ka et l'Actuel, aux volumes généralement réduits, est interprété comme représentatif de l'activité gravitaire annuelle du massif avec le climat actuel.Les données spectrales des échantillons datés ont permis de développer un index de la couleur du granite (GRIGRI) par combinaison des valeurs de réflectivité de deux longueurs d'onde différentes. Cet index est corrélé avec l'âge d'exposition (R=0.861) ; il a permis de proposer la datation de 10 échantillons d'âge inconnu à partir de leurs caractéristiques spectrales. / High mountain is particularly sensitive to climate variations. The raising temperature that is currently taking place due to climate change has a strong impact on the Mont Blanc massif rock walls: a higher rockfall (>100 m3) occurrence has been noticed, caused by permafrost thawing. The raising in number of rockfalls has been successfully correlated to warm periods at different timescales, e.g., during extreme warm episodes like the 2003 and 2015 heat waves, and during the last 30 years. According to the expected raising temperatures, during the 21st century rockfall occurrence should continue to rise.Rockfall frequency in the Mont Blanc massif before the Little Ice Age is still largely unknown. During Lateglacial and Holocene, high occurrence has been related to warm periods as well? In order to answer this question, this PhD thesis has four aims:i. To date several rockfalls having taken place in the central part of the Mont Blanc massif, in order to understand their frequency during Lateglacial and Holocene. Exposure age of rockfall scars is obtained using Terrestrial Cosmogenic Nuclide dating.ii. To verify possible relationships between high rockfall occurrence periods and post-glacial climate periods.iii. To quantify rockfall volumes by means of 3D reconstruction of the rockfall shapes, to explore the possible relationship between cumulate volumes and climate periods.iv. To study the relationship between exposure ages and colours of rock surfaces. Colours are quantified by reflectance spectroscopy.A total of 70 rock surfaces have been sampled during three field campaigns that took place in 2006, 2011 and 2015-2016. 63 exposure ages were obtained, ranging 30 ± 20 a to 100.50 ± 8.50 ka. Three age clusters can be correlated to warm periods, corresponding to: two Holocene Warm Periods (7.50 – 5.70 ka), the Bronze Age Optimum (3.35 – 2.80 ka) and the Roman Warm Period (2.35 – 1.75 ka). A fourth age cluster has been detected with ages ranging 4.91 – 4.32 ka. The biggest cluster, ranging 1.09 ka – recent, shows rather small volumes. This is interpreted as the normal erosion activity corresponding to the current climate.The samples reflectance spectra allowed to develop a granite colour index (GRIGRI) by combining the values of two different wavelengths. This index is correlated to the samples exposure age (R = 0.861), and has been used to date the exposure age of 10 samples where Terrestrial Cosmogenic Nuclide dating failed Écroulements Permafrost Lgm Datation Cosmogénique Holocène Rockfalls Permafrost Last Glacial Maximum Cosmogenic Nuclide dating Holocene 550
9	A floresta de Araucária em Monte Verde (MG): história sedimentológica, palinológica e isotópica desde o último máximo glacial Siqueira, Eliane de 12 November 2012 (has links) A regiäo de Monte Verde (Camanducaia, MG) está sìtuada a 1500 m de altitude, na porção sul da serra da Mantiqueira. Alvéolos do relevo serrano, como o entroncamento dos córregos do cadete e da Minhoca com o rio Jaguari, junto à sua área urbana, propìciaram o acúmulo de sucessões métricas de sedimentos argilo-arenosos em condiçöes favoráveis à formação de material turfoso e à preservação de palinomorfos. Nesta área, o presente estudo reconstitui, a partir da integração dos registros palinológico, sedimentológico (granulometria e minerais pesados) e geoquímico/isotópico (C e N) de três testemunhos rasos (até 230 cm), a evoluçäo e os possíveis controles sedimentares e paleoclimáticos do cenário paleoflorístico no Quaternário tardio, com especial atençäo para a Floresta de Araucária. O contexto geral registrado nos testemunhos é de planície de inundação fluvial, com cobertura arbórea próxima, e influência varìável de fluxos de encosta. Na parte montante do vale do cadete, obtiveram-se idades compreendidas entre 38695 - 40522 anos cal A.P., em 220 cm de profundidade, e 2060 - 1880 anos cal 4.P., em 5 cm. Na parte inferior da coluna, até cerca de 16000 anos A.P., há indícios de aumento de distalidade para cima. Entre cerca de 16000 e 3500 anos A.P., evidencia-se redução da influência da matéria orgânica de plantas terrestres, em detrimento de algas, possivelmente em momento de abeÍura relativa da cobertura florestal. Os últimos 3500 anos seriam de restabelecimento da cobeÍura florestal, possivelmente já nos moldes da existente hoje, com redução gradual do aporte de areia. Mais a jusante do mesmo vale, as idades ficaram compreendidas entre 26764-26023 anos cal 4.P., em 210 cm de profundidade, e 2350 - 2150 anos cal A.P., em 10 cm, A parte inferior do intervalo, mais antiga que 20830-20370 anos cal A.P., é dominada por influência de áreas fontes locais, graníticas. Em 20000 anos A.P., fontes distais, metamórficas, passam a atuar, com aumento da influência de algas. Nos últimos 5000 a 6000 anos A.P., tem-se o readensamento da Floresta de Araucária, com manutenção de brejos, sob condiçöes climáticas frias e úmidas. Os resultados sugerem que as mudanças climáticas nos últimos 40 mil anos em Monte Verde não foram acentuadas a ponto de exercer grande impacto florístico e que houve predomínio de Araucaria e elementos associados a essa floresta durante todo intervalo estudado, sob condições climáticas frias e úmidas. / he Monte Verde region (Camanducaia, MG) is located in the southern portion of the Mantiqueira Range, with 1500 m of elevation. Relief alveoli, as the junction of cadete and Minhoca creeks with Jaguari River, sited close to the urban area, propitiated the accumulation of metric sucessions of sandy-mud sediments, under cond itions favorable to the formation of peat material and preservation of paìynomorphs. ln this area, the present study integrates palynological, sedimentological (grain size and heavy minerals) and geochemical/isotopic (C and N) records of three shallow cores (up to 230 cm deep) to reconstruct the evolution and possible sedtmentary and paleoclimatic controls of the Laie Quaternary paleofloristic scenario, with special emphasìs in the Araucaria Forest. The general sedimentary context recorded in the cores is a river floodplain close to tree cover areas, and with variable influence of slope flows. On the upstream Cadete valley, were obtained ages of 38695-40522 cal years BP, at the deep of 220 cm, and 2060-1880 cal years BP, at 5 cm. From the bottom of the column until about 16000 BP, there is evidence of increased distality upwards The time interval between about 16000 and 3500 yr BP shows a reduction in the influence of organic matter derived from terrestrial plants, to the detriment of algae, possibly in a moment of relative opening of the forest cover. The last 3500 years would be characterized by the restoration of forest cover, possibly similar to the existing today, with gradual reduction of the sand supply ln the downstream of the same valley, the ages vary from 26,764 fo 26,023 cal years BP, at 210 cm deep, to 2350 to 2150 cal years BP, at 10 cm. The lower part of the sedimentary column, older than 20830-20370 AP\' is dominated by the influence of local granitìc sources areas. ln 20000 years BP, distal metamorphic sources begin to act paralel with a increased influence of algae. over the last 5000-6000 years, a increase of Araucaria Forest is recorded, with maintenance of weflands under cold and wet climatic conditions. This results suggest that climate changes during the last 40 k years in Monte Verde region were not sufficient to exert great floristic impact. Araucaria and associated forest elements predominated during the whole studied interval, under cold and wet weather conditions. Araucaria Forest Floresta de Araucária Isotopes Isótopos Last Glacial Maximum Palinologia Palinology Sedimentologia Sedimentology Último Maximo Glacial
10	Cranial Morphological Distinctiveness Between Ursus arctos and U. americanus Hillesheim, Benjamin James 01 May 2017 (has links) Despite being separated by millions of years of evolution, black bears (Ursus americanus) and brown bears (Ursus arctos) can be difficult to distinguish based on skeletal and dental material alone. Complicating matters, some Late Pleistocene U. americanus are significantly larger in size than their modern relatives, obscuring the identification of the two bears. In the past, fossil bears have been identified based on differences in dental morphology or size. This study used geometric morphometrics to look at overall differences in cranial shape and used step-wise discriminant analysis to identify specific characters that distinguish cranial morphology between black and brown bears. Such differences could prove important in identifying fossil bears when crania are present but teeth are missing. Furthermore, being able to properly identify U. arctos and U. americanus crania is important in understanding evolutionary and ecological distinctions among both fossil and modern bears. Principal components, discriminant, and thin plate spline analyses indicated a clear morphological separation between the crania of U. americanus and U. arctos and highlighted key identifying features including a more convex forehead and a narrower, more elongate rostrum in U. arctos than U. americanus. Ursidae Geometric morphometrics Ursus americanus Ursus arctos Last Glacial Maximum Biodiversity Ecology and Evolutionary Biology Evolution Paleontology

Search results