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Empirical Relations in Properties of Unconsolidated Quartz Sands and Silts Pertaining to Water Flow
Author(s) -
Wiebenga William A.,
Ellis W. R.,
Kevi L.
Publication year - 1970
Publication title -
water resources research
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.863
H-Index - 217
eISSN - 1944-7973
pISSN - 0043-1397
DOI - 10.1029/wr006i004p01154
Subject(s) - porosity , sorting , geology , flow (mathematics) , yield (engineering) , hydraulic conductivity , geotechnical engineering , volumetric flow rate , quartz , grain size , void ratio , soil science , mineralogy , mechanics , mathematics , materials science , geometry , geomorphology , soil water , composite material , paleontology , physics , algorithm
During a laboratory investigation using radiotracers, empirical formulas were developed to replace the ambiguous or incorrect Dupuit‐Forchheimer assumption used in relationships governing the flow of water through porous, unconsolidated materials ranging from clay to coarse sands or fine gravels. The Dupuit‐Forchheimer assumption states that the ratio of specific flow rate to average flow velocity is equal to porosity, but it is not specified whether true porosity or void ratio or specific yield, also called effective porosity, is meant. The hydraulic conductivity shows a good correlation with the maximum 10% grain size, and the ratio of specific flow rate to average flow velocity shows good correlation with functions of specific yield and percentile sorting coefficient. From field measurements of specific flow rate and average flow velocity the specific yield can be computed.