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West Elk Mine <br />2.04 -51 Rev. 06/05- PR10, 03/06- PR10, 04/06- PR10, 09/07- PR12; 05/22- MR462 <br /> <br /> <br />2.04.7 Hydrology Description <br /> <br />The purpose of this section is to provide a broad overview of surface water and groundwater <br />hydrology for the permit area. Important subjects relative to hydrology are also addressed in other <br />sections including: Geology (2.04.6), Climatology (2.04.8), Soils (2.04.9), and Vegetation (2.04.10). <br />For information pertaining to alternate water supply, refer to Section 2.05.6. <br /> <br />To complete specialized research and evaluation, and devote particular attention to hydrologic and <br />subsidence phenomena resulting from mining, including the probable hydrologic consequences of <br />mining, MCC retained Wright Water Engineers, Inc. (WWE) of Denver, and Glenwood Springs, <br />Colorado. WWE has more than 50 years of experience on diverse water resource assignments. <br />MCC also retained HydroGeo, Inc. (now Hydrogeology Solutions, Inc. (HSI)) to review the <br />Hydrologic Characterization of the South of the Divide, Southern Panels, and Sunset Trail areas, as <br />well as the monitoring plans. HydroGeo and HIS have completed the hydrologic monitoring and <br />Annual Hydrology Reports for the WEM since 2001. <br /> <br />2.04.7(1) Groundwater Information <br /> <br />West Elk Mine had historically been considered a dry mine. Previous studies by MCC and its <br />consultants have shown that groundwater inflows encountered within the mine workings were <br />associated with perched conditions within the Upper and Lower Coal Members of the Mesaverde <br />Formation. These studies concluded that there was no stratigraphic unit above the Rollins <br />Sandstone that had the stratigraphic continuity or water-yielding capacity to be considered a <br />potential regional aquifer (see previous Figures 5A, 5B, 5C, 5D, 5E, and 5F). See Section 2.04.6 <br />(Geology Description) for a detailed discussion of the geologic units associated with, and in close <br />proximity to, the West Elk Mine workings. See also Exhibits 17A, 18, and 18B for additional <br />discussions relative to groundwater conditions and relationships. <br /> <br />Within West Elk Mine, groundwater inflows have largely manifested themselves as dripping <br />roof inflows from sandstone channels located in the lower portion of the Mesaverde Formation, <br />floor inflows associated with the underlying sandstone unit, rib/roof inflows associated with <br />fractures storing finite volumes of groundwater, and, as manifested in early 1996, damage zones <br />associated with fault systems. Conceptual groundwater flow is shown on Figure 7F and the <br />potentiometric surface of the groundwater in the E Seam is presented on Map 1 of Exhibit 71. <br /> <br />In early March 1996, B Seam development mining of the B East Mains near the Northeast Panels <br />intersected a SE-NE trending fault system (B East Mains (BEM) Fault) which initially produced <br />about 500 gpm. This same fault was subsequently crossed by mining several times with <br />observed groundwater inflows reaching as much as 2,500 gpm. Each progressive mining <br />intersect of the BEM Fault was generally down-dip from the previous one resulting in a <br />relatively large initial inflow that diminished over time. Each new intersection with the fault <br />system generally resulted in the loss of inflow from the previous mined crossing of the BEM <br />Fault. <br /> <br />In mid-January 1997, a second SW-NE trending fault system was intersected in the 14 Southeast <br />Headgate. Inflows from this fault system (14 Southeast Headgate (14 HG) Fault) were initially