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Download mountain building - Catawba County Schools
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MOUNTAIN BUILDING Michele Holler FACTORS AFFECTING DEFORMATION • Deformation refers to all the changes in the original shape and /or size of a rock body • Stress is the force per unit area acting on a solid • The changes in shape or volume is called strain • There are four factors that influence the strength of a rock and how it will deform. They are temperature, confining pressure, rock type and time TEMPERATURE AND PRESSURE • Rock deforms permanently in two ways: brittle deformation and ductile deformation • At the surface, where confining pressure (think of hot spots) and temperatures are low, rocks act like brittle solids and fracture. This is called brittle deformation or brittle fracture • At depth, where temperatures and pressure is high, rocks show ductile behavior. Ductile deformation produces a change in the rock size or shape without fracture ROCK TYPE • Mineral composition and texture greatly affect how a rock will deform • Rocks, like granite and basalt, that have strong internal bonds will fail by brittle fracture • Sedimentary and foliated metamorphic rocks will deform by ductile flow. Examples are gypsum, rock salt, and shale • Rocks of intermediate strength, like marble and limestone, may also behave in a ductile manner TIME • How long a stress is applied to a rock also plays a role in deformation • Forces that are unable to deform a rock when first applied may cause a rock to flow if maintained over a long period of time THE THREE TYPES OF STRESS • Tensional stress-when rocks are pulled in the opposite directions. Causes the material to be stretched • Compressional stresswhen rocks are squeezed or shortened • Shear stress-causes a body to be distorted with no changes in volume THREE TYPES OF FOLDS • Folds are a series of wave-like ripples • ANTICLINES-formed by upfolding or arching • SYNCLINES-are downfolds or troughs and are a limb of an anticline • MONOCLINES-large step-like folds in otherwise horizontal sedimentary strata. Are prominent in the Colorado plateau FAULTS • • 1. 2. 3. 4. Are fractures in the crust along which movements occurs There are four major types of faults: Normal faults Reverse faults Thrust faults Strike-slip faults NORMAL FAULTS • Hanging wall block moves down relative to the footwall • Most have steep dips of about sixty degrees • Movement is mainly in a vertical direction with some horizontal movement • Results in lengthening or extension of the crust from tensional stress REVERSE FAULTS • Hanging wall block moves up relative to the footwall • Are high angle faults with dips greater than 45 degrees • Most are small and only cause local displacement • Result from compressional stress THRUST FAULTS • Are reverse faults with dips less than 45 degrees • Hanging wall moves up and over the footwall • Have large-scale movement • Caused by compressional forces STRIKE-SLIP FAULTS • Movement is horizontal and parallel to the trend or strike • Produce a trace that is visible over great distances • Consists of a zone of parallel fractures • Produce large earthquakes • Crushed and broken rocks are easily eroded • Example is the San Andreas JOINTS • FRACTURES WITH NO MOVEMENT • MOST OCCUR IN ROUGHLY PARALLEL GROUP • RESULT IN LARGE SCALE REGIONAL STRESSES FOLDED MOUNTAINS • Formed primarily by folding • Caused by compressional stresses • Thrust faulting produces fold and thrust belts that have displaced the folded rock layers horizontally FAULT-BLOCK MOUNTAINS • Caused by large-scale normal faults and tensional stress • Examples include the Teton Range in Wyoming and the Sierra Nevada in California • Grabens which are like trenches and horsts which are the uplifted structures are formed with this type of mountain graben horst DOMES AND BASINS • Domes are structures produced by up warping like the Black Hills of South Dakota • Basins are down warped structures with a circular shape. Found in Michigan and Illinois MOUNTAIN BUILDING AT CONVERGENT BOUNDARIES • Most mountain building occurs here • Colliding plates provide the compressional forces that fold, fault and metamorphose sediments OCEAN-OCEAN CONVERGENCE • When two oceanic plates collide • Produces volcanic mountains • Examples are the Aleutian Islands OCEAN-CONTINENTAL CONVERGENCE • Forms a continental volcanic arc • Andes are an example • An accretionary wedge is formed which is an accumulation of different sedimentary and metamorphic rocks • Forms volcanic and folded mountains CONTINENT-CONTINENT CONVERGENCE • Form folded mountains • When the Eurasian and India plate collided they formed the Himalayas DIVERGENT BOUNDARIES • OCCUR MAINLY ON THE OCEAN FLOOR • FORM FAULT BLOCK MOUNTAINS • EXAMPLE IS THE MID-ALTLANTIC RIDGE NON-BOUNDARY MOUNTAINS • Some upwarped mountains, fault-block mountains and volcanic mountains are not formed at plate boundaries • Examples are the Hawaiian islands CONTINENTAL ACCRETION • Accretion is when the fragments get stuck to or embedded into the continent • Terranes are crustal fragments that has a geologic history distinct from the joining terranes • Accretion of mountain arcs may result in mountains ISOSTASY • Floating crust in gravitational balance • Mountains stand high because they have buoyant crustal roots that extend dense into the deeper mantle • Isostatic adjustment is when a new level of gravitational equilibrium is reached ISOSTATIC ADJUSTMENT • BECAUSE OF ISOSTASY, DEFORMED AND THICKENED CRUST WILL UNDERGO REGIONAL UPLIFT DURING MOUNTAIN BUILDING AND A LONG PERIOD AFTERWARDS • EROSION CAUSES THE CRUST TO RISE
