Biology:Geology of the Appalachians
The geology of the Appalachians dates back more than 1.1 billion years to the Mesoproterozoic era [1] when two continental cratons collided to form the supercontinent Rodinia, 500 million years prior to the later development of the range during the formation of the supercontinent Pangea. The rocks exposed in today's Appalachian Mountains reveal elongate belts of folded and thrust faulted marine sedimentary rocks, volcanic rocks and slivers of ancient ocean floor – strong evidence that these rocks were deformed during plate collision. The birth of the Appalachian ranges marks the first of several mountain building plate collisions that culminated in the construction of the supercontinent Pangea with the Appalachians and neighboring Anti-Atlas mountains (now in Morocco) near the center. These mountain ranges likely once reached elevations similar to those of the Alps and the Rocky Mountains before they were eroded.[2][3]
Geological history
Proterozoic Era
Grenville orogeny and formation of supercontinent Rodinia
The first mountain-building tectonic plate collision that initiated the construction of what are today the Appalachians occurred during the Mesoproterozoic period at least one billion years ago when the pre-North American craton called Laurentia collided with other continental segments, notably Amazonia. All the other cratons of the earth also collided at about this time to form the supercontinent Rodinia and were surrounded by one single ocean. Mountain-building referred to as the Grenville orogeny occurred along the boundaries of the cratons. The present Appalachian Mountains have at least two areas which are made from rock formations that were formed during this orogeny - the Blue Ridge Mountains and the Adirondacks. [1]
Breakup of Rodinia and formation of the Iapetus Ocean
After the Grenville orogeny, the direction of the continental drift reversed, and the single supercontinent Rodinia began to break up. The mountains formed during the Grenvillian era underwent erosion due to weathering, glaciation, and other natural processes, resulting in the leveling of the landscape. The eroded sediments from these mountains contributed to the formation of sedimentary basins and valleys. For example, in the what is now the southern United States, the Ococee Basin was formed. Seawater filled the basin. Rivers from the surrounding countryside carried clay, silt, sand, and gravel to the basin, much as rivers today carry sediment from the midcontinent region to the Gulf of Mexico. The sediment spread out in layers on the basin floor. The basin continued to subside, and over a long period of time, probably millions of years, a great thickness of sediment accumulated. [4] Eventually, the tectonic forces pulling the two continents apart became so strong that an ocean formed off the eastern coast of the Laurentian margin. This was called the Iapetus Ocean and was the precursor of the modern Atlantic Ocean. The rocks of the Valley and Ridge province formed over millions of years, in the Iapetus. Shells and other hard parts of ancient marine plants and animals accumulated to form limey deposits that later became limestone. This is the same process by which limestone forms in modern oceans. The weathering of limestone, now exposed at the land surface, produces the lime-rich soils that are so prevalent in the fertile farmland of the Valley and Ridge province. [5]
During this continental break-up, around 600 million to 560 million years ago, volcanic activity was present along the tectonic margins. There is evidence of this activity in today's Blue Ridge Mountains. Mount Rogers, Whitetop Mountain, and Pine Mountain are all the result of volcanic activity that occurred around this time. [6] Evidence of subsurface activity, dikes and sills intruding into the overlying rock, is present in the Blue Ridge as well. For instance, mafic rocks have been found along the Fries Fault in the central Blue Ridge area of Montgomery County, VA. [7]
Paleozoic Era
During the earliest part of the Paleozoic Era, the continent that would later become North America straddled the equator. The Appalachian region was a passive plate margin, not unlike today's Atlantic Coastal Plain Province. During this interval, the region was periodically submerged beneath shallow seas. Thick layers of sediment and carbonate rock were deposited on the shallow sea bottom when the region was submerged. When seas receded, terrestrial sedimentary deposits and erosion dominated.[9]
During the Middle Ordovician Period (about 458-470 million years ago), a change in plate motions set the stage for the first Paleozoic mountain building event (Taconic orogeny) in North America. The once quiet Appalachian passive margin changed to a very active plate boundary when a neighboring oceanic plate, the Iapetus, collided with and began sinking beneath the North American craton. With the creation of this new subduction zone, the early Appalachians were born.[9]
Volcanoes grew along the continental margin, coincident with the initiation of subduction. Thrust faulting uplifted and warped older sedimentary rock laid down on the passive margin. As mountains rose, erosion began to wear them down. Streams carried rock debris downslope to be deposited in nearby lowlands.[9]
Mountain building continued periodically throughout the next 250 million years (Caledonian, Acadian, Ouachita, Hercynian, and Alleghanian orogenies). Continent after continent was thrust and sutured onto the North American craton as the Pangean supercontinent began to take shape. Microplates, smaller bits of crust too small to be called continents, were swept in one by one to be welded to the growing mass.[9]
By about 300 million years ago (Pennsylvanian Period) Africa was approaching the North American craton. The collisional belt spread into the Ozark-Ouachita region and through the Marathon Mountains area of Texas. Continental collisions raised the Appalachian-Ouachita chain to a lofty mountain range on the scale of the present-day Himalayas. The massive bulk of Pangea was completed near the end of the Paleozoic Era (Permian Period) when Africa (Gondwana) plowed into the continental agglomeration, with the Appalachian-Ouachita mountains near the middle.[9]
Mesozoic Era and later
Pangea began to break up about 220 million years ago, in the Early Mesozoic Era (Late Triassic Period). As Pangea rifted apart a new passive tectonic margin was born, and the forces that created the Appalachian, Ouachita, and Marathon Mountains were stilled. Weathering and erosion prevailed, and the mountains began to wear away.[9]
By the end of the Mesozoic Era, the Appalachian Mountains had been eroded to an almost flat plain.[9] It was not until the region was uplifted during the Cenozoic Era that the distinctive topography of the present formed.[10] Uplift rejuvenated the streams, which rapidly responded by cutting downward into the ancient bedrock. Some streams flowed along weak layers that define the folds and faults created many millions of years earlier. Other streams downcut so rapidly that they cut right across the resistant folded rocks of the mountain core, carving canyons across rock layers and geologic structures.[9] The ridges of the Appalachian Mountain core represent erosion-resistant rock that remained after the rock above and beside it was eroded away.[9]
Physiographic Provinces
The geographic boundaries of the Appalachian Mountains follows a definition that accounts for all the land mass in the United States and Canada used by the US Geological Survey and the Geologic Survey of Canada using the science of physiography. The US uses the term Appalachian Highlands and Canada uses the term Appalachian Uplands to define contiguous regions that have similar geology, topography, history, and native plant and animal communities. (The Appalachian Mountains are not synonymous with the Appalachian Plateau which is one of the provinces of the Appalachian Highlands).[citation needed]
The Appalachian Basin
The Appalachian Basin is a foreland basin containing Paleozoic sedimentary rocks of Early Cambrian through Early Permian age. From north to south, the Appalachian Basin Province crosses New York, Pennsylvania, eastern Ohio, West Virginia, western Maryland, eastern Kentucky, western Virginia, eastern Tennessee , northwestern Georgia, and northeastern Alabama. The northern end of the Appalachian Basin extends offshore into Lakes Erie and Ontario as far as the United States–Canada border. The Appalachian Basin Province covers an area of about 185,500 square miles (480,000 km2). The province is 1,075 miles (1,730 km) long from northeast to southwest and between 20 and 310 miles (30 and 500 km) wide from northwest to southeast.[11]
The northwestern flank of the basin is a broad homocline that dips gently southeastward off the Cincinnati Arch. A complexly thrust faulted and folded terrane (Appalachian Fold and Thrust Belt or Eastern Overthrust Belt), formed at the end of the Paleozoic by the Alleghanian orogeny, characterizes the eastern flank of the basin. Metamorphic and igneous rocks of the Blue Ridge Thrust Belt that bounds the eastern part of the Appalachian Basin Province were thrust westward more than 150 miles (240 km) over lower Paleozoic sedimentary rocks.[11]
Coal, oil, and gas production
The Appalachian Basin is one of the most important coal producing regions in the U.S. and one of the biggest in the world. Appalachian Basin bituminous coal has been mined throughout the last three centuries. Currently, the coal primarily is used within the eastern U.S. or exported for electrical power generation, but some of it is suitable for metallurgical uses. Economically important coal beds were deposited primarily during Pennsylvanian time in a southeastward-thickening foreland basin. Coal and associated rocks form a clastic wedge that thickens from north to south, from Pennsylvania into southeast West Virginia and southwestern Virginia.[12]
The Appalachian Basin has had a long history of oil and gas production. Discovery of oil in 1859 in the Drake Well, Venango County, Pennsylvania, marked the beginning of the oil and gas industry in the Appalachian Basin. The discovery well opened a prolific trend of oil and gas fields, producing from Upper Devonian, Mississippian, and Pennsylvanian sandstone reservoirs that extend from southern New York, across western Pennsylvania, central West Virginia, and eastern Ohio, to eastern Kentucky.[11]
A second major trend of oil and gas production in the Appalachian Basin began with the discovery in 1885 of oil and gas in Lower Silurian Clinton sandstone reservoirs in Knox County, Ohio. By the late 1880s and early 1900s, the trend extended both north and south across east-central Ohio and included several counties in western New York where gas was discovered in Lower Silurian Medina Group sandstones. About 1900, large oil reserves were discovered in Silurian and Devonian carbonate reservoirs in east-central Kentucky. Important gas discoveries from the Lower Devonian Oriskany Sandstone in Guernsey County, Ohio, in 1924; Schuyler County, New York, in 1930; and Kanawha County, West Virginia, in 1936 opened a major gas-producing trend across parts of New York, Pennsylvania, Maryland, Ohio, West Virginia, Kentucky, and Virginia.[11] Another drilling boom in the Appalachian Basin occurred in the 1960s in Morrow County, Ohio, where oil was discovered in the Upper Cambrian part of the Knox Dolomite.[11]
Crystalline Appalachians
The Blue Ridge, Piedmont, Adirondack, and New England Provinces are collectively known as the Crystalline Appalachians, because they consist of Precambrian and Cambrian igneous and metamorphic rocks.[13]
The Blue Ridge Thrust Belt Province underlies parts of eight states from central Alabama to southern Pennsylvania. Along its western margin, the Blue Ridge is thrust over the folded and faulted margin of the Appalachian basin, so that a broad segment of Paleozoic strata extends eastward for tens of miles, buried beneath these subhorizontal crystalline thrust sheets.[14] At the surface, the Blue Ridge consists of a mountainous to hilly region, the main component of which are the Blue Ridge Mountains that extend from Georgia to Pennsylvania. Surface rocks consist mainly of a core of moderate-to high-rank crystalline metamorphic or igneous rocks, which, because of their superior resistance to weathering and erosion, commonly rise above the adjacent areas of low-grade metamorphic and sedimentary rock. The province is bounded on the north and west by the Paleozoic strata of the Appalachian Basin Province and on the south by Cretaceous and younger sedimentary rocks of the Gulf Coastal Plain. It is bounded on the east by metamorphic and sedimentary rocks of the Piedmont Province.[15]
The Adirondack and New England Provinces include sedimentary, meta-sedimentary, and plutonic igneous rocks, mainly of Cambrian and Ordovician age, similar lithologically to rocks in the Blue Ridge and Piedmont Provinces to the south. The uplifted, nearly circular Adirondack Mountains consist of a core of ancient Precambrian rocks that are surrounded by upturned Cambrian and Ordovician sedimentary rocks.[15]
References
- ↑ 1.0 1.1 Thomas, William A.; Hatcher, Jr., Robert D. (2021). "Southern-Central Appalachians-Ouachitas Orogen". Encyclopedia of Geology 4. "The foundations of the Appalachian-Ouachita orogen were laid when the assembly of supercontinent Rodinia was completed. The collisional events were accompanied by high-grade metamorphism and magmatism during the Grenville orogeny in the time span of 1300–950 Ma.".
- ↑ Berardelli, Phil (November 2, 2009). "The Mountains That Froze the World". Science magazine. AAAS. http://news.sciencemag.org/sciencenow/2009/11/03-02.html?etoc.
- ↑ "Geology of the Great Smoky Mountains". USGS. http://geology.er.usgs.gov/eespteam/Mtleconte/website/geology.html?etoc.
- ↑ Clark, Sandra H. B. (1996). Birth of the Mountains: The Geologic Story of the Southern Appalachian Mountains. United States Geologic Survey. pp. 4. https://pubs.usgs.gov/gip/birth/birth.pdf.
- ↑ Clark, Sandra H. B. (1996). Birth of the Mountains: The Geologic Story of the Southern Appalachian Mountains. United States Geologic Survey. pp. 4. https://pubs.usgs.gov/gip/birth/birth.pdf.
- ↑ Rankin, James W. (1993). The volcanogenic Mount Rogers Formation and the overlying glaciogenic Konnarock Formation: Two late Proterozoic units in southwestern Virginia. USGS. doi:10.3133/b2029.
- ↑ Kaygi, Patti Boyd (1994). The Fries Fault near Riner, Virginia: an example of a polydeformed, ductile deformation zone. VT Works.
- ↑ Blakey, Ron. "Paleogeography and Geologic Evolution of North America". Global Plate Tectonics and Paleogeography. Northern Arizona University. http://jan.ucc.nau.edu/rcb7/nam.html.
- ↑ 9.0 9.1 9.2 9.3 9.4 9.5 9.6 9.7 9.8 This article incorporates public domain material from the United States Geological Survey website http://geomaps.wr.usgs.gov/parks/province/appalach.html.
- ↑ Poag, C. Wylie; Sevon, William D. (September 1989). "A record of Appalachian denudation in postrift Mesozoic and Cenozoic sedimentary deposits of the U.S. Middle Atlantic continental margin". Geomorphology 2 (1–3): 119–157. doi:10.1016/0169-555X(89)90009-3. Bibcode: 1989Geomo...2..119P.
- ↑ 11.0 11.1 11.2 11.3 11.4 This article incorporates public domain material from the United States Geological Survey website http://certmapper.cr.usgs.gov/data/noga95/prov67/text/prov67.pdf by R.T. Ryder.
- ↑ This article incorporates public domain material from the United States Geological Survey website http://pubs.usgs.gov/pp/p1625c/CHAPTER_A/CHAPTER_A.pdf by Leslie F. Ruppert.
- ↑ "The Sedimentary Appalachians". NYC Regional Geology. http://3dparks.wr.usgs.gov/nyc/valleyandridge/sedimentaryapp.htm.
- ↑ Harris, L.D.; Harris, A.G.; de Witt, Jr., W.; Bayer, K.C. (1981). "Evaluation of the southern eastern overthrust belt beneath Blue Ridge-Piedmont thrust". American Association of Petroleum Geologists Bulletin 65 (12): 2497–2505. doi:10.1306/03b599ef-16d1-11d7-8645000102c1865d.
- ↑ 15.0 15.1 This article incorporates public domain material from the United States Geological Survey website http://certmapper.cr.usgs.gov/data/noga95/prov71/text/prov71.pdf by Robert C. Milici.
- Goodge, J. W.; Vervoort, J. D.; Fanning, C. M.; Brecke, D. M.; Farmer, G. L.; Williams, I. S.; Myrow, P. M.; DePaolo, D. J. (2008). "A positive test of East Antarctica–Laurentia juxtaposition within the Rodinia supercontinent". Science 321 (5886): 235–240. doi:10.1126/science.1159189. ISSN 0036-8075. PMID 18621666. Bibcode: 2008Sci...321..235G. http://sites.coloradocollege.edu/pmyrow/files/2012/09/APositiveTestOfEastAntarcticaLaurentia.pdf. Retrieved 4 February 2016.
- Loewy, S. L.; Dalziel, I. W. D.; Pisarevsky, S.; Connelly, J. N.; Tait, J.; Hanson, R. E.; Bullen, D. (2011). "Coats Land crustal block, East Antarctica: A tectonic tracer for Laurentia?". Geology 39 (9): 859–862. doi:10.1130/G32029.1. Bibcode: 2011Geo....39..859L. https://www.researchgate.net/publication/232551854. Retrieved 24 January 2016.
External links
Original source: https://en.wikipedia.org/wiki/Geology of the Appalachians.
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