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West Elk Mine <br />to 16 percent, but with a permeability of .001 Darcy or less. These marine sandstones could <br />store water but don't. Inflows from roof channels or springs not associated with faulting <br />are rare or nonexistent. Indeed exploration drilling on or near MCC's coal leases during <br />the past 40 years has not encountered significant water in the coals or sandstones. Perched <br />aquifers are rarely encountered and have restricted lateral extents. <br />The low transmissivity and poor aquifer characteristics of the coals have also been <br />evidenced by interception of water bearing fault systems in the B Seam development. On <br />four separate instances, significant water bearing fault system (>2000gpm) was crossed. <br />The coal 10' to 15' away from the fault systems did not exhibit any additional water flows <br />or leakage. Within the fault damage zone, fractures in the roof and floor strata allowed for <br />minor water leakage from the main fault conduit. However no perceptible water flow <br />through the coal seam occurred except for within the fault blades where the crushed and <br />brecciated coal exists. If the coal seams were permeable and transmissive, theses fault zones <br />would be depressurized and mostly drained with obvious increases in water flows in a wide <br />halo around the fault zones. <br />The B Seam roof is predominately mudstones with occasional coal riders and tine grain <br />laminated sandstones. More sandstone overlies the B Seam than the E or F Seams, but this <br />sand appears to be more of tabular or sheet-type sand and does not hold much perched <br />water. Also, the immediate roof shales are harder, less slickensided, and are more stable in <br />the presence of any water encountered. <br />The D through F Seam coals conformably overlie the Bowie Sandstones. The strata <br />containing the coals are fluvial in nature containing a mixture of sandstone channels, <br />overbank splay deposits, fine-grained siltstones and mudstones, and carbonaceous <br />mudstones with minor coal layers. Only the E Seam sandstone roof channels are <br />considered to be a signi£-cant water source. Mayo (2004) estimates the maximum inflow <br />rate from non-faulted sandstone channels to be 500 gpm diminishing gradually over 6 <br />months. <br />Water inflows from tectonic faults and their associated damage zones have been well <br />documented in the B Seam mining. These northeast -southwest trending faults are known <br />to be sufficiently dilated to provide a conduit for sporadic groundwater movement. Prior <br />to 1996, several fractures and faults encountered within West Elk Mine produced water at <br />a maximum initial rate of 50 to 100 gpm for a couple of days before diminishing to a few <br />drops or a wet area. These fractures and faults generally contain a finite amount of storage <br />volume with limited recharge. <br />Based on Mayo's work (1998, 2000, 2003, and 2004) the water drained by tectonic fault <br />systems resides within the dilated faults and fractures of competent sandstones, primarily <br />the Rollins Sandstone, with lesser amounts stored in the Bowie Sandstones. Each fault <br />system is independent of others relative to storability. Newly encountered fault zones will <br />rapidly drain water from the most open fractures of the underlying Rollins Sandstone and <br />overlying Bowie Sandstones. The flow rates diminish as the water travels through more <br />tortuous paths of less dilated damage zone fractures and as the fractures above the <br />1.04-46 Revised November 2004 PRt 0 <br />