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151	Mass Balance of the High-Arctic Glacier Nordenskiöldbreen, Svalbard, in a Changing Climate / Massbalansen över den högarktiska glaciären Nordenskiöldbreen, Svalbard, och dess klimatförändring Gustavsson, Maja January 2019 (has links) Melting glaciers are the major contributor to sea level rise. Glaciers are sensitive indicators of climate change and current experience strong developments in a rapidly warming Arctic environment. Time-series of the mass balance of the glacier Nordenskiöldbreen are constructed by using height observations from the stake measurements on the glacier. The connection between the glacier mass balance and monthly averaged weather parameters observed at nearby meteorological stations will be analyzed. The total net balance on glacier Nordenskiöldbreen is found to be negative (-0.09 m w.e. per year) between 2005 and 2017. The mass balance during the summer season correlates strongest with maximum air temperature, while the winter balance is found to be mostly influenced by cloud cover and temperature, rather than precipitation. The results show that precipitation observed at nearby weather stations are not representative for precipitation amounts observed on the glacier. / Glaciärer som smälter är en av de största bidragen till den förhöjda havsnivån. Det är därför viktigt att studera Svalbards glaciärer för att kunna svara på hur den arktiska uppvärmningen påverkar issystemen. En tidsserie över massbalansen för glaciären Nordenskiöldbreen skapades genom höjdobservationer från stavmätningar befintliga på glaciären. I nästa steg analyserades kopplingen mellan glaciärmassbalansen och väderparametrarna som observerats vid närliggande meteorologiska stationer. Den totala netbalansen på glaciären Nordenskiöldbreen visade sig vara negativ (-0.09 m w.e. per år) mellan år 2005 och 2017. Massbalansen under sommarsäsongen korrelerade starkast med maximal lufttemperatur medan vinterbalansen var mest påverkad av molntäcke och temperatur, snarare än nederbörd. Resultaten visar att nederbörd observerad vid närliggande väderstationer inte är representativ för nederbördsmängder observerade på glaciären. Mass balance glacier Nordenskiöldbreen climate change Massbalans glaciär Nordenskiöldbreen klimatförändringar Meteorology and Atmospheric Sciences Meteorologi och atmosfärforskning
152	A Regional Analysis of Changing Climate Conditions and Glacier Mass Balance in Svalbard / En regional analys av förändrade klimatförhållanden och den glaciala massbalansen på Svalbard Bergman, Ottar January 2019 (has links) The Arctic archipelago of Svalbard has experienced among the greatest increases in temperature on Earth in the last few decades. The changing climatic conditions have a large impact on the glacier mass balance. This study makes use of a highresolution model dataset with data on climatic and glacier conditions on Svalbard from 1957 to 2018. The model dataset is used to analyse the spatiotemporal variability in glacier mass balance across Svalbard and linking those changes to long-term trends in meteorological conditions. The study is focused on the spatial gradients in trends between two regions in Svalbard, the coldest part of the archipelago, Nordaustlandet and the milder southern part of the main island Spitsbergen. The north eastern (NE) region is found to have a greater increase in annual air temperature over the simulation period with 5.5 °C compared to 3.5 °C for the south western (SW) region. The increase in annual summer temperatures is much smaller with a total increase of 1 °C for the NW and 1.5 °C for the SW. Both regions show a small, but significant, increase of precipitation. Relative humidity and cloud cover in the NE are increasing slightly over the time period, probably due to retreating sea ice cover. Glacier melt and runoff are increasing in both regions, which is contributing to significant negative trends in the mass balance. The increase in melt and run off is stronger in the SW than in the NE. There’s a strong correlation between summer air temperature and glacier mass balance, melt and runoff. Refreezing in the NE is decreasing much faster than in the SW. Refreezing is strongly correlated with annual air temperatures in the NE and not in the SW, probably due to lower temperatures in the NE region. glacier mass balance model data climate change Svalbard Earth and Related Environmental Sciences Geovetenskap och miljövetenskap
153	Carbon Flux and Weathering Processes in Icelandic Glacial-Fed Rivers Quiroga, Allison 01 April 2018 (has links) An investigation into the carbon dynamics and weathering processes occurring in Icelandic glacial-fed streams was conducted during the spring to summer seasonal transition in June of 2017. Four major outlet rives were sampled from the glaciers of Gígjökull, Steinsholtsjökull, Sólheimajökull, and Falljökull. Markarfljót, the major river that Gígjökull, Steinsholtsjökull, and many other glaciers drain into, was also sampled. Longitudinal sampling occurred at all sites to capture downstream trends in the hydrogeochemistry and carbon dynamics. Distinct differences in geochemistry between glacier surface meltwater, sub-glacial waters, pro-glacial lake water, and post-mixed downstream samples were evident in the data. Glacier surface streams were characterized by relatively colder water temperatures, lower specific conductivity, lower total dissolved solids (TDS) and ion concentrations, and more enriched δ13CDIC values than downstream samples. The THINCARB model was used to calculate the total dissolved inorganic carbon (TDIC), excess partial pressure of carbon dioxide (EpCO2), and percent contribution to TDIC by bicarbonate (HCO3), carbonate (CO3), and carbonic acid and dissolved CO2 (H2CO3). All sites showed a slight decreasing trend in DIC and EpCO2 downstream. The calculated CO2 flux ranged from 1.14 × 107 g/yr to 2.80 × 109 g/yr. The DIC flux ranged from 6.81 × 107 g/yr to 8.44 × 109 g/yr. The average carbon within the CO2 fluxing in these rivers accounts for 0.0004% of the annual, global flux of carbon. The δ13C values were the most variable throughout the study and indicate there are multiple sources influencing the river downstream. This study suggests that, despite previous assumptions and estimations, these glacial-fed rivers act as sources of CO2; however, the samples from this study only provide a snapshot into the carbon flux dynamics during the Spring to Summer seasonal transition. In most samples, HCO3 was the dominant species contributing to DIC content within the rivers, suggesting that DIC is being transported to the ocean as HCO3 but sourced to the atmosphere as CO2. By acting as sources of CO2 to the atmosphere, the process of glaciers melting, which drive geochemical processes within the rivers, are contributing to a positive feedback loop with respect to global warming. Geochemistry glacier climate change global warming Environmental Sciences Fresh Water Studies Geochemistry Glaciology
154	Late Quaternary Glacier Fluctuations and Vegetation Change in the Northwestern Ahklun Mountains, Southwestern Alaska Axford, Yarrow L. 01 May 2000 (has links) This research examines moraine and lacustrine records of glacier fluctuations, in combination with palynological records of vegetation change, from the previously unstudied northwestern Ahklun Mountains in southwestern Alaska. Morain mapping reveals that ice-cap outlet glaciers in the study area extended ca. 60 km from the center of the Ahklun Mountians ice dome during the early Wisconsin (sensu lato), and ca. 40 km during the late Wisconsin. Correlations with well-studied moraines in the southern Ahklun Mountains indicate an asymmetry of glaciation over the range, with ice-cap outlet glaciers more extensive to the south. This asymmetry was more striking during the early Wisconsin (s.l.) than during the late Wisconsin. Alpine glaciers have repeatedly advanced from cirques within the study area. Because these alpine glaciers were confluent or sub-confluent with outlet glaciers during the late Wisconsin maximum, the alpine-glacier moraine record is relatively young. Lacustrine sedimentology from Little Swift Lake records significant retreat of alpine glaciers ca 12.8 ka (coeval with the onsent of the North Atlantic Younger Dryas). Moraines upvalley of the lake suggests a minor glacier (or rock glacier) advance occurred ca 5.5 ka. Lacustrine records of vegetation from Little Swift Lake extend back to ca. 13.4 ka. Most vegetation changes resulted from the post-glacial spread of trees and shrubs, including Betula, alnus, and Picea, to their modern ranges. However, pollen assemblages and other paleoclimate proxies suggest some major changes in late-glacial and Holocene climate. Major vegetation change, most notably the dramatic expansion of Poaceae, occurred ca. 100 yr after the 12.8-ka glacier retreat and persisted for more than 2 ka. The inferred reversal to dry (and possibly cool) climate was followed by a period of exceptionally productive mesic conditions during the early Holocene, ca. 11 to 9 ka. The pattern of latest-Quaternary climate changes documented in this study may be evidence that, as previous workers have concluded regarding the Pleistocene glaciations, the late-glacial and early Holocene climate of the Ahklun Mountains region was strongly modulated by changes in the proximity and temperature of the Bering Sea. late quatrenary glacier fluctuations vegetation change northwestern ahklun mountains southwestern alaska Geology
155	Improving the Physical Processes and Model Integration Functionality of an Energy Balance Model for Snow and Glacier Melt Sen Gupta, Avirup 01 May 2014 (has links) The Hindu-Kush Himalayan region possesses a large resource of snow and ice, which acts as a freshwater reservoir for irrigation, domestic water consumption or hydroelectric power for billions of people in South Asia. Monitoring hydrologic resources in this region is challenging because of the difficulty of installing and maintaining a climate and hydrologic monitoring network, limited transportation and communication infrastructure and difficult access to glaciers. As a result of the high, rugged topographic relief, ground observations in the region are extremely sparse. Reanalysis data offer the potential to compensate for the data scarcity, which is a barrier in hydrological modeling and analysis for improving water resources management. Reanalysis weather data products integrate observations with atmospheric model physics to produce a spatially and temporally complete weather record in the post-satellite era. This dissertation creates an integrated hydrologic modeling system that tests whether streamflow prediction can be improved by taking advantage of the National Aeronautics and Space Administration (NASA) remote sensing and reanalysis weather data products in physically based energy balance snow melt and hydrologic models. This study also enhances the energy balance snowmelt model by adding capability to quantify glacier melt. The novelty of this integrated modeling tool resides in allowing the user to isolate various components of surface water inputs (rainfall, snow and glacier ice melt) in a cost-free, open source graphical-user interface-based system that can be used for government and institutional decision-making. Direct, physically based validation of this system is challenging due to the data scarcity in this region, but, to the extent possible, the model was validated through comparison to observed streamflow and to point measurements at locations in the United States having available data Physical Processes Model Integration Functionality Energy Balance Model Snow Glacier Melt Civil and Environmental Engineering
156	Strain and structure of a temperate, maritime glacier : Te Moeka o Tuawe / Fox Glacier, South Westland, New Zealand : thesis submitted in fulfilment of the degree of Master of Science in Physical Geography, at Massey University, Palmerston North, New Zealand Appleby, John Richard Unknown Date (has links) The study of glaciers has an immense significance for understanding and predicting global environmental change. The Earth is a dynamic system, consisting of individual units such as the cryosphere, an understanding of which may provide the basis for predicting future environmental change on a global scale. The dynamics of a glacier, a major indicator of the climatic and environmental situation is often presented as supraglacial structures, which reflect glacier formation, deformation and flow. Although structural attributes such as folds, faults, crevasse traces and foliation are commonly described in glaciers, the origin and significance of many of these structures remains unclear. This research project mapped the surface structures of Fox Glacier, using remote sensing in the form of aerial photographs and field observations, to produce a structural glaciological interpretation of the glacier surface, structural field maps of individual structures, and a schematic structural evolution of Fox Glacier. In addition, cumulative strain, and strain rates were calculated for three different areas of the lower Fox Glacier. The relationship between the observed structures and the measured strain rates has also been considered. Fox Glacier is located in the South Westland region of the South Island of New Zealand. From the Main Divide of the Southern Alps up to 3000m altitude, Fox Glacier flows for 13 km, terminating at an altitude of 270 metres in temperate rainforest, 17 km from the present coastline. The steep gradient allows for relatively rapid ice flow. Despite being a very dynamic glacier, very little research has been carried out on Fox Glacier in recent years with most research in the area being concentrated on its neighbour the Franz Josef, and even more so on the glaciers of the Eastern side of the Main Divide (e.g. the Tasman and Mueller glaciers). There is a high level of spatial variability in structural types observed, and the cumulative strain and strain rates measured on the surface of the Fox Glacier, with the variations being linked to valley topography including long-profile gradient and valley width. Strain rates of 208.78 y-1 and -162.06 y-1 were recorded on Fox Glacier. A relationship can be determined between observed glaciological structural features and measured strain rates, suggesting strain rate has an influence on the type, magnitude, location and frequency of these features, however, the study is only a ‘snap-shot’ of the strain conditions experienced in the most dynamically active time, during the summer ablation season. Developing predictive models of the structural evolution of glaciers may help further understanding of how glaciers respond to a change in climatic input, especially climatic warming. This is particularly important for larger ice sheet outlet glaciers whose structure and flow appear to reflect and control dynamics of the ice sheet behind glaciology Fox Glacier New Zealand structure strain
157	Reconstruction du bilan de masse des glaciers alpins et impact d'un changement climatique Gerbaux, Martin 31 October 2005 (has links) (PDF) Dans ce travail, nous avons adapté et mis en oeuvre le modèle de neige CROCUS pour le calcul et la reconstruction du bilan de masse des glaciers alpins. Le bilan de masse est calculé au pas horaire à partir des données de température, vitesse du vent, humidité, précipitations, rayonnement infra-rouge, rayonnement solaire direct et diffus et nébulosité. Il est spatialisé sur l'ensemble de la surface du glacier avec un pas horizontal de 200 m. Les données météorologiques pour la validation du modèle proviennent du modèle SAFRAN. La glace de glacier a été introduite dans CROCUS (albédo, rugosité), et la chaîne SAFRAN/CROCUS a été validée à partir de mesures de terrain et de reconstructions photogrammétriques du bilan de masse de surface et d'images satellite de la ligne de neige. Le bilan de masse pour la période 1981-2004 est reconstruit pour les glaciers de St Sorlin et d'Argentière, en bon accord avec les données disponibles.<br /><br />Le modèle permet de tester la sensibilité du bilan de masse des glaciers aux paramètres météorologiques. Pour des amplitudes de variations des paramètres météorologiques compatibles avec un changement climatique réaliste (prévisions climatiques de type IPCC), la température se révèle le paramètre dominant, et la sensibilité de l'altitude de la ligne d'équilibre est de 125 m.K-1, ou même 160 m.K-1 si la variation concomitante du rayonnement infra-rouge est prise en compte. L'impact de la variabilité des paramètres et des combinaisons de paramètres entre eux n'est pas négligeable par rapport à l'impact d'un changement de la moyenne météorologique (tendance).<br /><br />Des simulations longues de bilan de masse ont été effectuées sur la période 1800-2165, en utilisant des résultats de simulations climatiques réalisées par plusieurs modèles de circulation générale dans le cadre de l'IPCC AR4. D'après le modèle, le glacier de St Sorlin devrait disparaître avant 2100. Glacier bilan de masse climat CROCUS SAFRAN
158	Etude de la dynamique des séracs du Géant ( Massif du Mont Blanc) Reynaud, Louis 04 April 1973 (has links) (PDF) Pour appliquer aux glaciers les lois de la mécanique des milieux continus, on considère une surface et un lit lissés à l'échelle de quelques dizaines de mètres. Lorsque la surface d'un glacier ainsi lissée ne peut quand même pas être assimilée à un plan, le calcul des contraintes en profondeur doit faire intervenir les variations de pente de la surface lissée et les variations de la vitesse superficielle Ce calcul a été fait par Lliboutry (1969), dans le cas où les lignes de niveau de la surface restent parallèles entre elles et perpendiculaires à l'axe d'écoulement, en approchant les vitesses et les contraintes à la surface dans une partie limitée du glacier par des polynômes. En appliquant à la chute de glace des séracs du Géant les expressions obtenues pour les contraintes, un premier calcul peu précis le conduit à un frottement contre le lit à peu près proportionnel à la pression normale, cela en quatre points. Afin de préciser ces résultats qui utilisaient quelques vitesses superficielles seulement,. mesurées en 1960 et une restitution de photographies aériennes prises en 1958, nous avons fait des mesures de vitesses et un relevé de la surface, par photogrammétrie terrestre . Ce travail sur la chute de séracs du Glacier du Géant, fait partie d'une étude en cours, plus vaste, concernant toute la dynamique de la Mer de Glace . sérac glacier du Géant photogrammétrie mesures contraintes naturelles mécanique
159	Glaciers and climate in northern Sweden during the 19th and 20th century Klingbjer, Per January 2004 (has links) <p>Our understanding of the climate of northern Sweden during the late Holocene is largely dependent on proxy-data series. These datasets remain spatially and temporally sparse and instrumental series are rare prior to the mid 19th century. Nevertheless, the glaciology and paleo-glaciology of the region has a strong potential significance for the exploration of climate change scenarios, past and future. The aim of this thesis is to investigate the 19th and 20th century climate in the northern Swedish mountain range. This provides a good opportunity to analyse the natural variability of the climate before the onset of the industrial epoch. Developing a temporal understanding of fluctuations in glacier front positions and glacier mass balance that is linked to a better understanding of their interaction and relative significance to climate is fundamental in the assessment of past climate.</p><p>I have chosen to investigate previously unexplored temperature data from northern Sweden from between 1802 and 1860 and combined it with a temperature series from a synoptic station in Haparanda, which began operation in 1859, in order to create a reliable long temperature series for the period 1802 to 2002. I have also investigated two different glaciers, Pårteglaciären and Salajekna, which are located in different climatic environments. These glaciers have, from a Swedish perspective, long observational records. Furthermore, I have investigated a recurring jökulhlaup at the glacier Sälkaglaciären in order to analyse glacier-climate relationships with respect to the jökulhlaups. </p><p>A number of datasets are presented, including: glacier frontal changes, in situ and photogrammetric mass balance data, in situ and satellite radar interferometry measurements of surface velocity, radar measurements, ice volume data and a temperature series. All these datasets are analysed in order to investigate the response of the glaciers to climatic stimuli, to attribute specific behaviour to particular climates and to analyse the 19th and 20th century glacier/climate relationships in northern Sweden.</p><p>The 19th century was characterized by cold conditions in northern Sweden, particularly in winter. Significant changes in the amplitude of the annual temperature cycle are evident. Through the 19th century there is a marked decreasing trend in the amplitude of the data, suggesting a change towards a prevalence of maritime (westerly) air masses, something which has characterised the 20th century. The investigations on Salajekna support the conclusion that the major part of the 19th century was cold and dry. The 19th century advance of Salajekna was probably caused by colder climate in the late 18th and early 19th centuries, coupled with a weakening of the westerly airflow. The investigations on Pårteglaciären show that the glacier has a response time of ~200 years. It also suggests that there was a relatively high frequency of easterly winds providing the glacier with winter precipitation during the 19th century.</p><p>Glaciers have very different response times and are sensitive to different climatic parameters. Glaciers in rather continental areas of the Subarctic and Arctic can have very long response times because of mass balance considerations and not primarily the glacier dynamics. This is of vital importance for analyzing Arctic and Subarctic glacier behaviour in a global change perspective. It is far from evident that the behaviour of the glacier fronts today reflects the present climate.</p> physical geography climate temperature glacier mass balance jökulhlaup responce time photogrammetry
160	Glaciers and climate in northern Sweden during the 19th and 20th century Klingbjer, Per January 2004 (has links) Our understanding of the climate of northern Sweden during the late Holocene is largely dependent on proxy-data series. These datasets remain spatially and temporally sparse and instrumental series are rare prior to the mid 19th century. Nevertheless, the glaciology and paleo-glaciology of the region has a strong potential significance for the exploration of climate change scenarios, past and future. The aim of this thesis is to investigate the 19th and 20th century climate in the northern Swedish mountain range. This provides a good opportunity to analyse the natural variability of the climate before the onset of the industrial epoch. Developing a temporal understanding of fluctuations in glacier front positions and glacier mass balance that is linked to a better understanding of their interaction and relative significance to climate is fundamental in the assessment of past climate. I have chosen to investigate previously unexplored temperature data from northern Sweden from between 1802 and 1860 and combined it with a temperature series from a synoptic station in Haparanda, which began operation in 1859, in order to create a reliable long temperature series for the period 1802 to 2002. I have also investigated two different glaciers, Pårteglaciären and Salajekna, which are located in different climatic environments. These glaciers have, from a Swedish perspective, long observational records. Furthermore, I have investigated a recurring jökulhlaup at the glacier Sälkaglaciären in order to analyse glacier-climate relationships with respect to the jökulhlaups. A number of datasets are presented, including: glacier frontal changes, in situ and photogrammetric mass balance data, in situ and satellite radar interferometry measurements of surface velocity, radar measurements, ice volume data and a temperature series. All these datasets are analysed in order to investigate the response of the glaciers to climatic stimuli, to attribute specific behaviour to particular climates and to analyse the 19th and 20th century glacier/climate relationships in northern Sweden. The 19th century was characterized by cold conditions in northern Sweden, particularly in winter. Significant changes in the amplitude of the annual temperature cycle are evident. Through the 19th century there is a marked decreasing trend in the amplitude of the data, suggesting a change towards a prevalence of maritime (westerly) air masses, something which has characterised the 20th century. The investigations on Salajekna support the conclusion that the major part of the 19th century was cold and dry. The 19th century advance of Salajekna was probably caused by colder climate in the late 18th and early 19th centuries, coupled with a weakening of the westerly airflow. The investigations on Pårteglaciären show that the glacier has a response time of ~200 years. It also suggests that there was a relatively high frequency of easterly winds providing the glacier with winter precipitation during the 19th century. Glaciers have very different response times and are sensitive to different climatic parameters. Glaciers in rather continental areas of the Subarctic and Arctic can have very long response times because of mass balance considerations and not primarily the glacier dynamics. This is of vital importance for analyzing Arctic and Subarctic glacier behaviour in a global change perspective. It is far from evident that the behaviour of the glacier fronts today reflects the present climate. physical geography climate temperature glacier mass balance jökulhlaup responce time photogrammetry

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