Hydrogeologic Units Of Lebanon     

Kamal Khair  Nizar Aker  Khalil Zahruddine 《Hydrogeology Journal》1992,1(2):34-49

Based on geomorphologic and hydrogeologic characteristics of its territory, Lebanon is divided into three provinces: the West Lebanon province, the Bekaa province, and the East Anti-Lebanon province. These provinces are subdivided into smaller hydrogeologic units, the basins and subbasins. Significant features used in the subdivision are faults, relief, anticlinal axes, river channels, and water divides. Recharge to groundwater is a percentage of the intake area, the percipitation rate over this area, and the infiltration rate of outcropping rocks. The amounts of recharged water over the three provinces are 1609, 914, and 19 Mm³, respectively. Discharge is surface water from springs and water wells along the Lebanese coast. The discharge from the Lebanese rivers exceeds 3700 Mm³/year, an appreciable amount of which comes from natural springs. The quantity of groundwater pumped by wells or flowing into neighboring countries and to the sea as submarine springs, may exceed 800 Mm³/year.  相似文献   

Effect of sub‐core scale heterogeneities on acoustic and electrical properties of a reservoir rock: a CO2 flooding experiment of brine saturated sandstone in a computed tomography scanner     

Binyam L. Alemu  Eyvind Aker  Magnus Soldal  Øistein Johnsen  Per Aagaard 《Geophysical Prospecting》2013,61(1):235-250

The effect of sub‐core scale heterogeneity on fluid distribution pattern, and the electrical and acoustic properties of a typical reservoir rock was studied by performing drainage and imbibition flooding tests with CO₂ and brine in a laboratory. Moderately layered Rothbach sandstone was used as a test specimen. Two core samples were drilled; one perpendicular and the other parallel to the layering to allow injection of fluids along and normal to the bedding plane. During the test 3D images of fluid distribution and saturation levels were mapped by an industrial X‐ray CT‐scanner together with simultaneous measurement of electrical resistivity, ultrasonic velocities as well as amplitudes. The results showed how the layering and the flooding direction influenced the fluid distribution pattern and the saturation level of the fluids. For a given fluid saturation level, the measured changes in the acoustic and electrical parameters were affected by both the fluid distribution pattern and the layering orientation relative to the measurement direction. The P‐wave amplitude and the electrical resistivity were more sensitive to small changes in the fluid distribution patterns than the P‐wave velocity. The change in amplitude was the most affected by the orientation of the layering and the resulting fluid distribution patterns. In some instances the change due to the fluid distribution pattern was higher than the variation caused by the change in CO₂ saturation. As a result the Gassmann relation based on ‘uniform' or ‘patchy' saturation pattern was not suitable to predict the P‐wave velocity variation. Overall, the results demonstrate the importance of core‐imaging to improve our understanding of fluid distribution patterns and the associated effects on measured rock‐physics properties.  相似文献   

Stress-Induced Fracturing of Reservoir Rocks: Acoustic Monitoring and μCT Image Analysis     

Srutarshi Pradhan  Anna M. Stroisz  Erling Fjær  Jørn F. Stenebråten  Hans K. Lund  Eyvind F. Sønstebø 《Rock Mechanics and Rock Engineering》2015,48(6):2529-2540

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Stochastic Modeling of Subseismic Faults Conditioned on Displacement and Orientation Maps     

Goodwin  Håvard  Aker  Eyvind  Røe  Per 《Mathematical Geosciences》2022,54(1):207-224

Mathematical Geosciences - Subseismic faults are small faults or fractures that may be difficult to determine but can have large consequences for fluid flow and pressure communication in the...  相似文献   

Accuracy of simplified transport estimations in narrow sea straits     

Eyvind Aas  Øyvind Endresen 《Ocean Dynamics》1999,51(4):441-451

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