The geology of part of an orogenic belt in western Sierra Leone,West Africa     

Peter M. Allen 《International Journal of Earth Sciences》1968,58(2):588-620

Zusammenfassung Die Sierra Leone unterteilt sich in zwei Haupteinheiten. Die östliche ist ein Teil des festen präkambrischen westafrikanischen Kratons und besteht aus hochgradig metamorphem Gestein und Granitgneisen. Die Strukturen verlaufen in vorherrschend NE-Richtung. Der westliche Teil enthält Elemente eines orogenen Gürtels, nämlich der Rokeliden, die entweder im späten Präkambrium oder frühen Paläozoikum entstanden sind und nach NNW streichen. Die Gesteinsserien, die den orogenen Gürtel bilden, setzen sich aus dem Kasila-System, einer unbenannten Gneisgruppe östlich davon, den Rokel River Series und den Marampa Schists zusammen. Die sich an das Kasila-System, umbenannt in Kasila-Gruppe, anschließenden Gneise und wahrscheinlich auch die Kasila-Gruppe selbst können mit dem Gestein des Kratons verglichen werden, sind jedoch während der Entstehung der Rokeliden neu überprägt worden. Sie bilden die Basis der Mulde, die Sedimente und vulkanisches Gestein aus den Rokel River Series und den Marampa Schists enthält. Die Rokel River Series sind neu benannt und unterteilen sich in die Rokel River Gruppe mit sechs Formationen und in die Taban Formation, die aus nach-orogener Molasse besteht. Die Marampa Schists sind neu benannt in Marampa Formation. Das Ausmaß der Metamorphose steigert sich über die Rokeliden nach WSW, und die Marampa Formation ist der am stärksten metamorphisierte Teil der geosynklinalen Ausfüllung.

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Sierra Leone is divisible into two major structural units. The eastern one is part of the stable Precambrian West African craton and consists of high grade metamorphic rocks and granitic gneisses. The foliation has a dominantly NE trend. The western unit contains the elements of an orogenic belt named the Rokelides, which formed in either late Precambrian or early Palaeozoic, and trends NNW. The rock groups which comprise the orogenic belt are the Kasila System, an unnamed group of gneisses on the east of it, the Rokel River Series and the Marampa Schists. The gneisses adjacent to the Kasila System, renamed Kasila Group, and also, probably, the Kasila Group can be correlated with rocks in the craton, but were refoliated during the Rokelide orogenesis. They constituted the basement to the geosyncline which contained sediments and volcanic rocks of the Rokel River Series and Marampa Schists. The Rokel River Series is renamed, and divided into Rokel River Group which contains six formations, and the Taban Formation which is post-orogenic molasse. The Marampa Schists are renamed the Marampa Formation. The intensity of metamorphism and deformation increases across the Rokelides towards the WSW and the Marampa Formation is the most highly metamorphosed part of the geosynclinal infilling.

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Résumé Le Sierra Leone peut se diviser en deux principales sections structurales. La section orientale fait partie du craton stable précambrien de l'Afrique occidentale, formé de roches métamorphiques de haute qualité et de gneiss de granit. La foliation a principalement une direction NE. La section occidentale contient les éléments d'une ceinture orogénique appelée les Rokelides qui ont été formées soit vers la fin de la période précambrienne, soit au début de la période paléozoique et en direction NNW. Les groupes rocheux qui comprennent la ceinture orogénique sont le Kasila System, un groupe de gneiss sans nom situé à son côté est, la Rokel River Series et les Marampa Schists. Les gneiss avoisinant le Kasila System, renommé Kasila Group et en toute probilité le Kasila Group également peuvent être rattachés aux roches du craton mais auraient été refoliés pendant l'orogenèse Rokelide. Ils ont formé la base du géosynclinal qui contient des sédiments et des roches volcaniques de la Rokel River Series et des Marampa Schists. La Rokel River Series a été renommée et divisée en Rokel River Group qui contient six formations et la Taban Formation qui est la mollasse post-orogénique. Les Marampa Schists ont été renommés la Marampa Formation. L'intensité du métamorphisme et de la déformation augmente vers WSW à travers les Rokelides, et la Marampa Formation est la partie la plus métamorphosée de l'accumulation géosynclinale.

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Martin J. Allen  S. M. Morrison 《Ground water》1973,11(2):6-10

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Constructing the Coronal Magnetic Field By Correlating Parameterized Magnetic Field Lines With Observed Coronal Plasma Structures     

Gary  G. Allen  Alexander  David 《Solar physics》1999,186(1-2):123-139

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A need for incentivizing field hydrology,especially in an era of open data: discussion of “The role of experimental work in hydrological sciences – insights from a community survey”*     

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The north liberty radio observatory of the University of Iowa     

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Transport of water in frozen soil IV. Analysis of experimental results on the effects of ice content     

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Jane?M.?HammarstromEmail author  Robert?R.?SealII  Allen?L.?Meier  John?C.?Jackson 《Environmental Geology》2003,45(1):35-57

Metal cycling via physical and chemical weathering of discrete sources (copper mines) and regional (non-point) sources (sulfide-rich shale) is evaluated by examining the mineralogy and chemistry of weathering products in Great Smoky Mountains National Park, Tennessee, and North Carolina, USA. The elements in copper mine waste, secondary minerals, stream sediments, and waters that are most likely to have negative impacts on aquatic ecosystems are aluminum, copper, zinc, and arsenic because these elements locally exceed toxicity guidelines for surface waters or for stream sediments. Acid-mine drainage has not developed in streams draining inactive copper mines. Acid-rock drainage and chemical weathering processes that accompany debris flows or human disturbances of sulfidic rocks are comparable to processes that develop acid-mine drainage elsewhere. Despite the high rainfall in the mountain range, sheltered areas and intermittent dry spells provide local venues for development of secondary weathering products that can impact aquatic ecosystems.Electronic Supplementary Material  Supplementary material is available for this article if you access the article at . A link in the frame on the left on that page takes you directly to the supplementary material.

Jane M. HammarstromEmail: Phone: +1-703-6486165Fax: +1-703-6486252

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