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Subsidence Evaluation for the <br /> Exhibit 60E Southern Panels, Apache Rocks West, & Sunset Trail Mining Areas Page 5 <br /> 3.0 FACTORS INFLUENCING SUBSIDENCE <br /> Subsidence may be influenced by the local geology in the following ways: <br /> 1. Geologic structure. Attitude of the bedrock, faulting, and jointing may affect the mine layout <br /> and mining method employed. In steeply dipping,faulted coal beds,for example,a mine layout <br /> and method, such as room-and-pillar or limited panel-pillar, may be required. Joints often <br /> control the way in which the roof rocks break, cave, and fracture,both underground and at the <br /> surface during mining and subsidence. In relatively flat-lying, unfaulted coal seams like the <br /> Southern Panels, Apache Rocks West, and Sunset Trail mining areas, there is latitude to <br /> develop the most efficient layout and method to recover a maximum amount of the coal <br /> resource with a minimum of impact. <br /> 2. Strength and behavioral properties of the rocks. These properties control the amount and rate <br /> of subsidence. Strong, brittle sandstones and siltstones tend to break and cave in large blocks <br /> on the mine floor. The bulking factor is greater for strong rocks than it is for soft,weak rocks. <br /> The greater bulking factor of strong, caved material commonly reduces the height of caving <br /> and the subsidence factor compared to soft, weak rocks. Conversely, the height of fracturing <br /> often is greater for strong,brittle rocks than it is for soft, weak rocks. <br /> 3. Stratigraphic sequence. The stratigraphic distribution of rock units (stratigraphic sequence) <br /> influences the effects of mining and subsidence. For example, strong and brittle sandstones in <br /> the mine roof,as discussed above,can reduce the height of caving compared to shales,whereas <br /> sandstones in the fractured zone above the caved zone may increase the height of fracturing <br /> compared to shales. Conversely, the height of caving may be increased and the height of <br /> fracturing decreased where weaker shale and claystones occur in the fractured zone above the <br /> coal seam to be mined. <br /> In addition, the lithology of the overburden rock may control the subsidence factor. The <br /> subsidence factor may be less where the overburden contains a greater proportion of thick, <br /> strong sandstones, and greater where the overburden contains thin, weak shales. In the <br /> Southern Panels, Apache Rocks West, and Sunset Trail mining areas, the first 200 to 300 feet <br /> of rocks above the E-seam consist primarily of siltstones, shales, claystones, local lenticular <br /> sandstones, and coal seams. <br /> 4. Moisture content. Wet or saturated conditions in the mine roof and overburden tend to reduce <br /> the bulking factor of the caved roof rocks. Therefore, the subsidence factor commonly is <br /> greater under wet conditions than it is in dry conditions. In general, the greater the saturation <br /> of the mine roof and overburden rocks, the greater the subsidence factor. <br /> 831-032.912 Wright Water Engineers, Inc. <br /> December 2020 <br />