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of permeabilities expected of poor aquifers or aquicludes (which may have permeabi- <br />lities of I.0 to 0.01 gpd /ft or 0.04 to 0.0004 meters /day), It is suggested that <br />more c mp.ictton than that performed at tip, Porn is necessary to nchLeve lower per - <br />meabilittee. This compaction over and above that performed at the Big Horn Mine <br />appears necessary to recreate zones of "perched" water. <br />The water supply to the alluvial valley floor (as shown in Figure 7) cowl also <br />be the alluvial aquifer (i.e., underflow) and this would require that the of <br />recharge located upstream would have to be protected. This Locally 'c• .1 si - <br />tion could also exist in any of the situations shown in previous f <br />Of the three hydrologic situations shown in Figures 4, 5, de- <br />tailed perched system of Figure 7, the multiple aquifer system''. gure 5 <br />appears the most difficult to reestablish. The situation shown :ure 6 is also <br />difficult to reestablish. Both cases require the recreation of = effective semi - <br />confining layer, a reclamation practice not yet attempted on such a scale. The <br />perched aquifer system of Figure 7 could be difficult to reestablish for the same_ <br />reason. The single unconfined aquifer system ahawn in Figure 4 appears to have the <br />highest probability for reestablishment. <br />Based upon many assumptions which are given below, we suggest that in the situa- <br />tion shown in Figure 4 no coal would be removed from production because the cri- <br />tical features of the hydrologic system could be reestablished. The situation shown <br />in Figure 5 would necessitate leaving the second, deeper coal seam in place if pres- <br />sures of ground water were sufficiently out of balance and the combined post - mining <br />pressure (or water table elevation) was deemed to adversely affect the subirrigation <br />system. The situation portrayed in Figure 6 would require leaving the clayey shale <br />in the vicinity of the alluvial valley floor in place and thus would require leaving <br />sufficient coal under the shale to maintain the confining bed. The upper coal would <br />be mineable. In the case of the alluvial valley floor in Figure 7, we suggest that <br />the hydrologic system could be reestablished and that all the coal shown could be <br />extracted if very selective placement and additional compaction of spoil in a manner <br />not now used in western surface mining were required. <br />In order to judge the probability for successful reclamation of these hypothe- <br />tical alluvial valley floors and reestablishment of their essential functions, we <br />have made the following assumptions: <br />1. The post - mining topography and elevation would be very similar <br />to that existing prior to mining such that the approximate distance <br />from the ground surface to the water table was retained; <br />2. The post- mining stream gradient (and flow) achieved the same quasi - <br />stable equilibrium state existing prior to mining in terms of erosion <br />and sedimentation; <br />3. A suitable plant growth medium was reestablished after mining; <br />4. Vegetative productivity and species composition were reestablished <br />after mining; <br />5. The areas of ground water recharge were not modified; <br />6. Water quality was maintained; and <br />7. It would not be economically feasible to reestablish aquicludes over <br />large areas. <br />The first two assumptions would not be correct in instances where the overburden <br />thickness is'thin relative to coal thickness. In such cases, post - mining topo- <br />graphy would be lowered by many meters. Those situations have not been examined an <br />a mine -by -mine basis but must instead be examined on a regional basis that encom- <br />passes entire basins. <br />