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flow theory in a fracture flow situation. Unless the observation wells aze in good communication with the major <br />• fractures providing flow to the pumped well, then less drawdown in the observation well will occur and overestimates <br />of permeability from this date will result. Pumped well data are often better indicators of average formation <br />permeability in fracture dominated systems. <br />Pumped well data from Exhibit 9A indicates that the Wadge Overburden has an average permeability ranging from <br />0.01 to 0.1 ft/day, which is consistent with the low yields observed in monitoring wells. The vertical permeability of <br />the confming units for the Wadge Overburden averages 0.1 ft/day, which is indicative of effective confinement and <br />relative isolation from other ground water aquifers. Storage coefficient values calculated from pump tests average 1.7 <br />x10-4, which is within the normal range for a low porosity, confined, artesian aquifer. <br />The recharge capacity of the Wadge overburden aquifer was calculated in the Eckman Park permit application using <br />the flow net analysis method of Walton (1962) to be 50,000 gpd/sq. mi. equivalent to about 0.1 Foot per year. <br />Calculation of aquifer recharge capacity was based upon the undisturbed overburden aquifer in the Eckman Pazk area, <br />where the potentiometric gradient is relatively steep in comparison to other portions of the Bound water basin. One <br />factor that was not considered in this analysis is that much of the overburden in this area is not saturated and that the <br />steep gradient is more a reflection of the structural dip of the lithologic units. Since there is a direct relationship <br />between the steepness of the potentiometric gradient and the actual aquifer recharge rate, the resulting figure is <br />considered to be a considerable overestimation of the actual recharge capacity over the entire Wadge overburden <br />aquifer. <br />A more reliable estimate of the recharge to the Wadge overburden aquifer may be based on the assumption that <br />recharge is approximately equal to calculated rates of total ground water flow in the Wadge overburden towazds the <br />center of the Twentymile Park Basin which may be calculated from standard flow net analysis. The flow net analysis <br />was performed between the potentiometric contour elevations of 6700 and 6900 feet as shown on Map 13, <br />• Twentymile Park Hydrology. The average hydraulic gradient in this area is approximately 2 percent and the width of <br />the flow path perpendicular to flow, based on the 6800 foot contour, is approximately 25,000 feet. An average <br />permeability for the Wadge overburden is about 0.3 gpd/sq. ft. (0.04 ft/day) and an average thickness of the aquifer is <br />75 feet. The standard flow net analysis equation is: <br />Q = KhIL <br />where: <br />Q = Flow rate (Bpd) <br />K = Permeability (gpd/sq. ft.) <br />h = Aquifer thickness (ft.) <br />I = Hydraulic gradient <br />L = Width of flow path perpendicular to flow (ft) <br />Substituting the above values into this equation yields an average flow rate of about 11,000 Bpd (0.02 cfs). <br />Regional uplift of the Twentymile Park Basin during Pleistocene times has resulted in numerous northwest trending <br />fault zones, which displace the lithologic units. The major fault zones within the permit and adjacent area are shown <br />on the Twentymile Pazk Hydrology Map (Map 13). Field studies in which water levels in well adjacent to fault zones <br />were monitored during pump tests indicate that the faults tend to act as bamers to lateral ground water movement. <br />The potentiometric levels on either side of the fault zones reflect the vertical displacement of the lithologic units. The <br />restriction of ground water flow across fault zones tends to influence movement in a direction parallel to the strike of <br />the faults. <br />• The storage characteristics of the Wadge overburden aquifer were evaluated in Permit 79-177 (Pages 779-51 and 779- <br />52). Using an equation developed by Lohman (1972) for storage capacity under typical hydrostatic pressure <br />conditions, the total storage capacity of the Wadge overburden aquifer over the entire area of the Twentymile Park <br />ground water basin was calculated to be 708,000 acre-feet. <br />PR 03-06 2.04-26 05/07/03 <br />