Browsing by Author "Yu, Jaehyung"
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Item Assessment of Water Resources in A Humid Watershed and A Semi-arid Watershed; Neches River Basin, TX and Canadian River Basin, NM(2013-07-16) Heo, JoonghyeokWater is the most important resource on Earth. Climate and land cover changes are two important factors that directly influenced water resources. This research provides important information for water resources management and contributes on understanding of the responses of water resources to climate and land cover changes in two different climates. The Neches River watershed located in a humid subtropical climate had a 0.7 ?C increase in temperature and a 16.3 % increase in precipitation. Developed and crop land covers increased whereas vegetation cover decreased, as a result of human activities. Hydrologic responses to climate and land cover changes resulted in the increases of surface runoff (15.0 %), soil water content (2.7 %), evapotranspiration (20.1 %), and a decrease of groundwater discharge (9.2 %). Surface runoff had an increasing trend with precipitation whereas soil water content was sensitive to changes in land cover, especially human intervention. The Canadian River watershed, a semi-arid watershed, experienced a 0.9 ?C increase in temperature and a 10.9 % decrease in precipitation. Land cover was converted from developed and crop lands into barren land and grass covers, as a result of the decrease in human activity. The change of grass and forest covers into bush/shrub cover is thought to be linked to climate change. Surface runoff, groundwater discharge, soil water content, and evapotranspiration were all decreased by 10.2 %, 10.0 %, 7.7 %, and 9.4%, respectively. Hydrologic parameters generally follow similar patterns to that of precipitation. The trend in water resources followed a similar trend of precipitation for the two watersheds with different climates; a humid watershed and a semi-arid watershed. The humid climate watershed, the Neches River watershed, experienced increasing trends in temperature and precipitation. Groundwater discharge was sensitive to changes in land cover caused by human activities. The semi-arid watershed, the Canadian River watershed, had an increase in precipitation and a decrease in precipitation. Conversion of developed and crop land covers into barren and grass land covers was thought to be the result of the decrease in human activity. The volume of soil water was relatively offset by a combination of precipitation changes and land-cover changes.Item Investigation of glacial dynamics in lambert glacial basin using satellite remote sensing techniques(Texas A&M University, 2006-04-12) Yu, JaehyungThe Antarctic ice sheet mass budget is a very important factor for global sea level. An understanding of the glacial dynamics of the Antarctic ice sheet are essential for mass budget estimation. Utilizing a surface velocity field derived from Radarsat three-pass SAR interferometry, this study has investigated the strain rate, grounding line, balance velocity, and the mass balance of the entire Lambert Glacier ?? Amery Ice Shelf system, East Antarctica. The surface velocity increases abruptly from 350 m/year to 800 m/year at the main grounding line. It decreases as the main ice stream is floating, and increases to 1200 to 1500 m/year in the ice shelf front. The strain rate distribution defines the shear margins of ice flows. The major ice streams and their confluence area experience the most severe ice deformation. The width of the shear margin decreases as it flows downstream except for the convergent areas with tributary glaciers. The grounding line for the main ice stream and the boundary of Amery Ice Shelf and surrounding tributary glaciers is delineated. The total basal melting is estimated to be 87.82 ?? 3.78 Gt/year for the entire Amery Ice Shelf. Compared with the ice flux (16.35 ?? 3.11 Gt/year) at the ice shelf front, basal melting is apparently the dominant discharging process of the system. The melting rate for the Amery Ice Shelf decreases rapidly from the grounding zone (21.64 ?? 2.17 m/year) to the ice shelf front (-0.95 ?? 0.14 m/year). The Lambert Glacial Basin contributes the total ice mass of 95.64 ?? 2.89 Gt/year to the ocean, which is equivalent to increasing the global sea level by 0.24 mm/year. Considering 90.54 ?? 1.55 Gt/year of snow accumulation, the entire Lambert Glacier ?? Amery Ice Shelf system is slightly negatively imbalanced at -5.09 ?? 3.46 Gt/year. Although the entire system is estimated to have a slight negative mass balance, three sub-glacial systems have a net positive mass balance due to a relatively high snow accumulation rate or relatively slow ice motion. Considering the large mass loss in West Antarctica, it is believed that the overall mass budget in Antarctica is negative based on this research.