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- Surface Geology / Rock Formations
- Formation Thickness (ft.) Lithology
- (Figure: Geological Formations GIS Map)
Historical GeologyIntroduction to Plate Tectonics The outermost portion of the Earth is composed of a series of large slabs called tectonic plates, or lithospheric platesi. These plates move very slowly (give approximate figure, if possible) over the surface of the Earth, powered by the flow in the interior mantleii. These ideas basically describe the theory of plate tectonicsiii. Figure w/ plates moving over the mantle w/ convection currents to show movement. Plate tectonics is important to the formation of geologic materials because the movement of the plates form mountain ranges and oceans. In some areas, tectonic plates will move away from one another, or diverge, and in the void space created by this divergence, magma wells up from the mantle to create new plate materialiv. In other areas, tectonic plates will crash into one another, or converge, and create mountain systems, like the Himalayas or the Alpsv. Continents are portions of tectonic plates that consist of lighter, older rocks that ride passively on the moving platesvi. Figure of diverging and converging plate margins w/ continent on top Volcanoes, earthquakes, and developing mountains can be found on the leading edge of a continent, which is the site of tectonic plate convergencevii. The trailing edge of a continent lies within a plate and is typically a low-relief, gentle coastal plain where thick sequences of sedimentary rocks can be foundviii. Currently, the pattern of plate movement is away from the center of the Atlantic Ocean and towards the Pacific Oceanix. Around the margin of the Pacific Ocean (where plates are converging) the continents are mountainous, and volcanoes and earthquakes are prevalentx. Near the Atlantic Ocean, the continents are much flatter with little geologic activity other than the deposition of sedimentsxi. Every half billion years or so, the flow direction in the mantle changes, and tectonic plate motion reversesxii. When plate movement changes, margins of continents undergo a transformation; diverging plates now become converging plates, and vice versaxiii. The history of plate movement show that those parts of continents that border ocean basins alternate repeatedly between two states: (1) the trailing edge margin of a continent with little tectonic activity and (2) the leading edge margin of a continent that has much tectonic activityxiv. These half billion year cycles are called Wilson Cycles, named after J. T. Wilson who discovered themxv. The mountain systems that are created by convergent margins are called orogens, and the creation of an orogen is called an orogenyxvi. Orogens form when previously passive margins become active margins due to the reversal of plate motionxvii. This causes the sedimentary deposits laid down during the passive margin stage to be compressed, deformed, and intruded by magma from the mantlexviii. For more in depth information, please visit (http://pubs.usgs.gov/publications/text/dynamic.html)
The next Orogenic event to deform the rocks around Raystown was the Acadian Orogeny, which occurred from the Silurian to the Devonian, or 380 to 350 million years agoxxiii. The cause of the Acadian Orogeny was the late Silurian/mid Devonian collision of the northern part of Avalon with the North American platexxiv. The oceanic Avalon plate was subducted under the North American platexxv. Deltas soon formed on the North American plate, and as the mountains rose, the deltas were pushed farther inland, creating cyclic sequences of rock unitsxxvi. Figure of the collision and uplift The final Orogenic event that deformed rocks seen on our trips was the Alleghenian Orogeny, which occurred from the Mississippian to the Permian, or 320 to 250 million years agoxxvii. The cause of the Alleghenian Orogeny is the continent-continent collision between the North American Plate and the Laurasian (African) Platexxviii. The Appalachian Mountains were formed on the North American plate, and were originally similar in size to the Himalayasxxix. There were many faults formed due to this collision, including low-angle thrust faults and many anticlines were formed in the forelandxxx. Figure of the collision and uplift The subsequent erosion of the rock units around Raystown has changed the Himalaya-sized Mountains of 250 million years ago to the smaller scale Appalachian mountains and the Ridge and Valley province we see today. This erosion began at the end of the Alleghenian Orogeny and is still continuing today. The less resistant rocks of the area, like carbonates and shales, are more easily eroded than the more resistant rocks of the area, like the sandstones. This imbalance in erosional rates created the valleys, where the less resistant rocks have eroded, and ridges, where the more resistant rocks are located.  
Formations'>Surface Geology / Rock Formations The prominent bedrock formations found beneath and on the banks of Raystown Lake include the Catskill, Foreknobs, and Scherr formations, all of which were created during the Upper Devonian age, roughly 360-370 million years before present (see historical geology section).34 These formations contain lithologies associated with sandstone, siltstone, mudstone, conglomerate and shale (a lithology is the physical character of a rock on the basis of such characteristics as color, mineralogic composition, and grain size).35 These lithologies are related to this region in accordance with the Valley and Ridge system. The Valley and Ridge structural providence is a classic example of a folded and faulted foreland mountain system, which underwent deformation during the Alleghany orogeny leading to the Appalachian Mountain system observable today.36 This system of folds and faults present within the Appalachians of south-central Pennsylvania is significant to the Raystown Lake region because the lithologies associated with the ridges are siliclatistic in origin (sandstone, siltstone, shale), just as those found in the Catskill, Foreknobs, and Scherr formations. These siliclastic materials comprise the composition of the ridge because they are less susceptible to weathering and erosion. These materials are more resistant due to the fact that their solubility is far less than that of the carbonate materials such as limestone, which principally make up the valley structure of system. The intricate Valley and Ridge system of folds and faults assisted by the action of weathering and erosion has created the conditions for which Raystown Lake now stands upon. The Catskill formation is the most significant of the three formations in relation to the lake and the creation of the dam not only because the Catskill underlies a majority of the lake but since this bedrock is primarily made up of sandstone, which erodes at a relatively slow rate and provides a strong base for the construction of a dam. To get a better understanding of the thickness, lithology, and fossils associated with these three formations refer to the figure below:
(Figure: Geological Formations GIS Map) 
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