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<br />7.O GROUND WATEN--Continued <br />7.4 Aquiler Tests <br />Aquifer Tests Reveal Differences in Aquifer Permeability <br />The alluvium is a more permeable aquifer than the bedrock. <br />Aquifer tests (fig. 7.4-1) measure the ability of a <br />formation to transmit water. The results of aquifer <br />tests in Area 61 are summarized in table 7.4-I. <br />The specific capacity of a well is the discharge <br />divided by the drawdown of the water level in the <br />well during pumping, as expressed in gallons per <br />minute per foot of drawdown. Where wells are <br />constructed similarly, aquifers with greater permea- <br />bility, such as the alluvium, have greater specific <br />capacities than aquifers with less permeability, such <br />as the Raton-Vermejo-Trinidad aquifer. The small <br />specific capacity of the Cuchara-Poison Canyon <br />aquifer indicated in table 7.4-I results because the <br />formations comprising this aquifer are saturated only <br />near the base in the area where the tests were pcr- <br />Cormed. Such aquifers have small specific capacities <br />because they have little water in them and are rapidly <br />drained by pumping, even if they are known to be <br />highly permeable, as in the case of the Cuchara- <br />Poison Canyon aquifer. <br />at about the same rate through coal and sandstone. <br />The apparently large rate ofground-water movement <br />through siltstone and shale in the Raton-Vcnncjo- <br />Trinidad aquifer is misleading because of a dispro- <br />portionately large hydraulic-conductivity measure- <br />ment in one 2-fool- thick zone of fractured siltstone. <br />Tests of shale and siltstone in the Raton-Vermcjo- <br />Trinidad aquifer usually show these rocks to be <br />nearly impermeable. <br />The transmissivity is the hydraulic conductivity <br />of an aquifer multiplied by its saturated thickness <br />and is an indication of the volume of water that an <br />aquifer can transmit, as expressed in feel squared per <br />day. Equal transmissivities can result from a thick <br />aquifer with small hydraulic conductivity or a thin <br />aquifer with large hydraulic conductivity. The data <br />in table 7.4-I indicate that the alluvium can transmit <br />much more water than bedrock, drat Iracturing can <br />increase the transmissivity of a bedrock aquifer, and <br />that in the Raton-Vermejo-Trinidad aquifer, coal <br />and sandstone have about the same transmissivity. <br />The hydraulic conductivity is the rate at which <br />ground water moves through a unit cross-sectional <br />area of an aquifer under a unit hydraulic gradient, as <br />expressed in feet per day. The data in table 7.4-I <br />indicate that ground water may tnovc more easily in <br />the alluvium than in [he bedrock, and that ground <br />water in the Raton-Vermejo-Trinidad aquifer moves <br />Aquifer test data are contained in Griggs (1948), <br />Dames and Moore (1978), Water, Waste, and Land, <br />Lld. (1980), Howard (1982), Colorado Water Re- <br />sources Division drillers' logs, and unpublished U.S. <br />Geological Survey data. <br /> <br />W u C <br />N , <br />- P <br />'^ <br /> <br />~ <br />'~ 5 <br />E m Y 'i <br /> <br />m <br />I <br />I ~ 3 y o 5 <br />~ YW o e9 - - ~-, Z ~ <br /> <br />a g <br />b W g <br />a J <br />C~ 5 <br />O - -,NO ~< O ,t 0 Z <br /> I I ^- a N n p <br />~ RY C O <br /> C' B <br /> ; ~ <br />6 Pm.e <br />~O- s p ~ e <br /> P 5 <br />