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101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aFractured rock hydrogeology /$feditor, John M. Sharp, Jr., The University of Texas, Austin, USA
205   $aFirst edition.
210  1$aBoca Raton :$cCRC Press,$d[2014].
210  4$d©2014
215   $a1 online resource (403 p.)
225 1 $aSelected papers on hydrogeology ;$v20
300   $aDescription based upon print version of record.
311   $a1-306-86619-7 
311   $a1-315-77882-3 
320   $aIncludes bibliographical references and index.
327   $aFront Cover; Contents; Dedication; Foreword; About the editor; List of contributors; 1. IAH Commission on Hardrock Hydrogeology (HyRoC): Past and present activities, future possibilities; 2. The conceptual model of weathered hard rock aquifers and its practical applications; 3. Similarities in groundwater occurrence in weathered and fractured crystalline basement aquifers in the Channel Islands and in Zimbabwe; 4. Outcrop groundwater prospecting, drilling and well construction in hard rocks in semi-arid regions
327   $a5. Sustainable yield of fractured rock aquifers: The case of crystalline rocks of Serre Massif (Calabria, Southern Italy)6. From geological complexity to hydrogeological understanding usingan integrated 3D conceptual modelling approach - insights from the Cotswolds, UK; 7. Characterising the spatial distribution of transmissivity in the mountainous region: Results from watersheds in central Taiwan; 8. Spring discharge and groundwater flow systems in sedimentary and ophiolitic hard rock aquifers: Experiences from Northern Apennines (Italy)
327   $a9. Fracture transmissivity estimation using natural gradient flow measurements in sparsely fractured rock10. Prediction of fracture roughness and other hydraulic properties: Is upscaling possible?; 11. Scale dependent hydraulic investigations of faulted crystalline rocks - examples from the Eastern Alps, Austria; 12. Methodology to generate orthogonal fractures from a discrete, complex, and irregular fracture zone network; 13. Remote sensing, geophysical methods and field measurements to characterise faults, fractures and other discontinuities, Barada Spring catchment, Syria
327   $a14. Using heat flow and radiocarbon ages to estimate the extent of recharge area of thermal springs in granitoid rock: Example from Southern Idaho Batholith, USA15. Tunnel inflow in granite - fitting the field observations with hybrid model of discrete fractures and continuum; 16. Uranium distribution in groundwater from fractured crystalline aquifers in Norway; 17. Technical quality of Norwegian wells in crystalline bedrock related to groundwater vulnerability
327   $a18. Exploration and characterisation of deep fractured rock aquifers for new groundwater development, an example from New Mexico, USA19. Use of several different methods for characterising a fractured rock aquifer, case study Kempfield, New South Wales, Australia; 20. Main features governing groundwater flow in a fractured Basalt Aquifer System of South-Eastern Australia; Colour plates; Series IAH-selected papers
330   $aFractured rocks extend over much of the world, cropping out in shields, massifs, and the cores of major mountain ranges. They also form the basement below younger sedimentary rocks; at depth; they represent a continuous environment of extended and deep regional groundwater flow. Understanding of groundwater flow and solute transport in fractured rocks is vital for analysis of water resources, water quality and environmental protection, geotechnical and engineering projects, and geothermal energy production. Book chapters include theoretical and practical analyses using numerical mode
410  0$aHydrogeology (International Association of Hydrogeologists) ;$v20.
606   $aHydrogeology
606   $aRocks$xFracture
615  0$aHydrogeology.
615  0$aRocks$xFracture.
676   $a553.7/9
702   $aSharp$b John Malcolm$cJr.,$f1944-
801  0$bFlBoTFG
801  1$bFlBoTFG
906   $aBOOK
912   $a9910787845003321
996   $aFractured rock hydrogeology$93806844
997   $aUNINA