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1	樹木年輪中放射性炭素14濃度測定による7-11世紀の太陽活動の復元 Nakamura, Toshio, Masuda, Kimiaki, Nagaya, Kentaro, Miyake, Fusa, 中村, 俊夫, 増田, 公明, 永治, 健太朗, 三宅, 芙沙 03 1900 (has links) 第23回名古屋大学年代測定総合研究センターシンポジウム平成22(2010)年度報告 Cosmogenic nuclide Solar cycle
2	Erosion Rates in and Around Shenandoah National Park, VA Determined Using Analysis of Cosmogenic 10Be Duxbury, Jane 13 February 2009 (has links) We use cosmogenic 10Be analysis of fluvial sediments and bedrock to estimate erosion rates (103 – 106 year timescale) and to infer the distribution of post-orogenic geomorphic processes in the Blue Ridge Province in and around Shenandoah National Park, VA. Our sampling plan was designed to investigate relationships between erosion rate, lithology, slope, and basin area. Fifty-nine samples were collected from a variety of basin sizes (<1 – 3351 km2) and average basin slopes (7 - 26°) in each of four different lithologies that crop out in the Park: granite, metabasalt, quartzite, and siliciclastic rocks. The samples include bedrock (n = 5), fluvial sediment from single-lithology basins (n = 43), and fluvial sediment from multilithology basins (n = 11): two of these samples are from rivers draining streams exiting the eastern and western slopes of the Park (Rappahannock and Shenandoah Rivers). Inferred erosion rates for all lithologies for fluvial samples range from 3.8 to 24 m/My. The mean erosion rate for single-lithology basins in the Park is 11.6 ± 4.8 m/My. Singlelithology erosion rates ranges for fluvial samples are: granite (basin size = ~0.4-40 km2 and slope = 11-23°), 7.9–22 m/My; metabasalt (basin size = ~1-25 km2 and slope = 11-19°), 4.8–24 m/My; quartzite (basin size = ~0.1-9 km2 and slope = 12-23°), 4.7–17 m/My; and siliciclastic rocks (basin size = ~0.3-13 km2 and slope = 18-26°), 6.2–17 m/My. The mean erosion rate for multilithology basins (basin size = ~1-3351 km2 and slope = 7-22°) is 10.2 m/My, and individually for the Shenandoah River 7.3 m/My and the Rappahannock River 13.8 m/My. Bedrock erosion rates range from 2.4-13 m/My across all lithologies, with a mean erosion rate of 7.9 ± 5.0 m/My. Grain-size specific 10Be analysis of four samples showed no consistent trend of concentration with grain size. These data support Hack’s dynamic equilibrium model. Slope and erosion rate are not well correlated, and mean erosion rates are similar for different lithologies. Cosmogenicallydetermined erosion rates in Shenandoah Park are similar to or lower than those reported elsewhere in the Appalachians including those of Matmon and others (2003), 25 to 30 m/My for metaclastic rocks in the steep Great Smoky Mountains, Reuter and others (2004), 4 – 54 m/My in Susquehanna River basin for shale, sandstone, and schist, and Sullivan and others (2006), 6-38 m/My in the micaceous schist and gneiss of the Blue Ridge Escarpment. Cosmogenic erosion rates (integration over 104 yrs) in the Blue Ridge province of Shenandoah National Park are consistent with long-term unroofing rates (integration over 107 yrs) estimated from U-Th/He measurements (11-18 m/My) in samples collected near the Blue Ridge Escarpment by Spotila and others (2004), and fission tracks (20 m/My) in the Appalachians by Naeser and others (2005). The consistency of denudation rates integrated over very different periods of time suggests steady erosion most likely in balance with, and driving isostatic uplift of rock. cosmogenic isotopes basin-scale erosion rates
3	樹木年輪中放射性炭素濃度測定による7-8世紀の太陽活動周期の研究 Nakamura, Toshio, Muraki, Yasushi, Masuda, Kimiaki, Nagaya, Kentaro, Miyake, Fusa, 中村, 俊夫, 村木, 綏, 増田, 公明, 永治, 健太朗, 三宅, 芙沙 03 1900 (has links) 名古屋大学年代測定総合研究センターシンポジウム報告 the Maunder minimum cosmogenic nuclide solar cycle
4	Investigating sediment source to sink processes in a post-orogenic landscape Marstellar, Tina L. 17 January 2012 (has links) In order to understand the life cycle of a mountain range, it is crucial to identify and quantify the processes that influence the rate of denudation, sediment flux through the landscape, and the resulting changes in relief over long time scales in tectonically-inactive regions. Geologic history and the quartz-rich lithologies make the southern Appalachian Mountains an ideal location for terrestrial cosmogenic nuclide (TCN) measurements aimed at studying erosion and denudation processes in an evolving post-orogenic landscape. We used in situ-produced TCN measurements of Beryllium-10 (10Be) to determine the denudation rate in ten catchments along the southern Appalachians. The locations selected are all within the east-draining Blue Ridge escarpment in North Carolina and Georgia. In five of the ten catchments we sampled two grain sizes, gravel and sand. In the remaining five catchments we sampled one grain size, sand. Our analysis provided erosion rates of 15 to 26 mm Ky-1 for the 0.025 to 0.050 cm sand samples and 12 to 20 mm Ky-1 for 3 to 8 cm gravel samples. We analyzed these TCN measurements in the context of several basin metrics, including slope and relief, derived from a digital elevation model (DEM). Our results provide evidence that most surficial basin metrics are not good predictors of denudation rates at a global scale, but can aid in predictions at a regional level. This finding supports the dynamic equilibrium hypothesis of landscape evolution and casts doubt on the possibility to estimate basin-wide denudation rates and watershed sediment supply at a global scale from simple metrics of basin morphology. Geochronology Cosmogenic Erosion Geological time Geochronometry
5	屋久杉年輪中14C濃度測定による7-8世紀の太陽活動周期長の研究 Nakamura, Toshio, Masuda, Kimiaki, Miyake, Fusa, 中村, 俊夫, 増田, 公明, 三宅, 芙沙 03 1900 (has links) 名古屋大学年代測定総合研究センターシンポジウム報告 solar dynamo cosmogenic nuclide solar cycle
6	The style and timing of the last deglaciation of Wester Ross, Northwest Scotland Mccormack, Deborah January 2011 (has links) The climate of the Wester Ross region of NW Scotland is particularly sensitive to fluctuations in the strength and latitude of the North Atlantic Gulf Stream. This was particularly apparent during the last deglaciation (14.7-12.9 ka), when overall climatic amelioration was interrupted by periods of cooling, the most significant being a 1.2 ka return to glacial conditions during the Younger Dryas (12.9-11.5 ka). Glacial readvances during these cooling episodes left behind numerous geomorphological features, which have been mapped and interpreted through a variety of methods, including fieldwork observations, aerial photography and digital elevation models, to form a detailed reconstruction of the style and timing of deglaciation. These methods were augmented by the study of 3D digital models, produced by combining 5cm resolution, Light Detection and Ranging (LiDAR) scans with colour photography, leading to the production of a detailed geomorphological map of a cirque formation in Torridon, Wester Ross, which was covered by an ice-sheet at the Last Glacial Maximum, and experienced localised ice flow during subsequent deglaciation and readvances. Six statistically comparable cosmogenic 10Be bedrock exposure ages give a Younger Dryas age for sites in Torridon and Applecross (Wester Ross), and have also been used to constrain the vertical extent of these ice fields. Reconstructions of these ice bodies revealed that the Torridon ice field (mean ELA, 482m) covered ~100km2, over twice the surface area covered by the Applecross ice field (~43km2). This could have resulted from the survival of ice in Torridon prior to the onset of the Younger Dryas cooling, and is tentativelty supported by pre-Younger Dryas cosmogenic 10Be exposure ages from this study and previous studies, which imply that ice existed close to the Wester Ross coastline and within central Torridon between 14-13ka. The Applecross ice field mean ELA (361m) was lowered by the presence of independent glaciers, which formed in low-lying troughs as snow was efficiently transferred to the NE by prevailing SW winds. Using empirical values from a global dataset, average annual Younger Dryas palaeoprecipitation values for the Torridon and Applecross ELAs are 2010 ± 266 and 2312 ± 534 mm a-1 respectively, suggesting a wetter climate than today. Palaeoprecipitation calculated using equations based on a climate model of NW Scotland, yield lower values between 1005 ± 67 mm a-1 and 1758 ± 118 mm a-1 for the Torridon ELA and 1205 ± 233 mm a-1 to 2109 ± 407 mm a-1 for the Applecross ELA, perhaps a more reliable estimate which reflect enhanced continentaility, promoted by the formation of sea ice on the NE Atlantic seaboard during the Younger Dryas.Despite the rapid warming observed in palaeotemperature proxies, studies of glacial geomorphology and basal shear stress suggest that initial deglaciation was slow, oscillatory and warm-based, leading to the formation of prominent retreat moraines in the lower valleys. This prolonged transition can be related to the northward migration of sea ice and the gradual reintroduction of a Gulf Stream-dominated maritime climate. Ice remaining in the central area down-wasted in-situ as the regional ELA increased, creating hummocky landscape. Finally, cosmogenic 10Be exposure ages indicate that glaciers (probably characerised by a polythermal regime) retreated into the high north-facing corries at approximately 11.8ka, depositing a series of flutes. 551.4
7	Quantifying Age and Rate of Landscape and Paleoenvironmental Change in Arid Tectonic Environments using Terrestrial Cosmogenic Nuclides: The Interplay of Climatic vs. Tectonic Drivers of Landscape Evolution in Arid Regions Hedrick, Kathryn 12 December 2017 (has links) No description available. Geology Geology Geomorphology Cosmogenic dating Tectonic Geomorphology
8	Rates of landscape development in the Transhimalaya of northern India: a framework for testing the links among climate, erosion, and tectonics Dortch, Jason Michael 03 August 2010 (has links) No description available. Geology cosmogenic geochronology ladakh himalaya glaciation strath
9	Slow denudation within an active orogen: Ladakh Range, northern India Reynhout, Scott A. 26 September 2011 (has links) No description available. Geomorphology cosmogenic denudation buzzsaw erosion glacial weathering
10	Search for an ultra high energy neutrino diffuse flux with the ANTARES telescope / Search for an ultra high energy neutrino diffuse flux with the ANTARES telescope Core, Laura 03 October 2013 (has links) Recherche des neutrinos de ultra haute energie avec le telescope ANTARES. Exploitations de 3 ans de donnees (2008-2011) pour la recherche d'un signal astrophysique, soit flux de Waxman Bahcall, soit neutrinos cosmogeniques. Utilization de technique d'analize multivariable. / Search for ultra high energy neutrinos with ANTARES telescope. Data analysis on 3 years of lifetime (2008-2011), to look for astrophysical signal, according to Waxman-Bahcall flux or cosmogenic one. Exploitation of multivariate analysis techniques. Neutrino Antares Astrophysique Analyse multivariable Physique Cosmogenic Neutrino Antares Astrophysics Multivariate analysis Physics Cosmogenic flux 530

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