Geologic history
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The geologic history of South America can be summarized in three different developmental stages, each corresponding to a major division of geologic time. The first stage encompassed Precambrian time (about 4.6 billion to 541 million years ago) and was characterized by a complex series of amalgamations and dispersals of stable blocks of protocontinental crust called cratons. The second stage coincides with the Paleozoic Era (about 541 to 252 million years ago), during which time the cratons and material accreted to them contributed to the formation first of the supercontinent Gondwana (or Gondwanaland) and then of the even larger Pangea (Pangaea). The third stage, in which the present continental structure emerged, occurred in the Mesozoic and Cenozoic eras (about the past 252 million years) and includes the breakup of Pangea and Gondwana, the opening of the South Atlantic Ocean, and the generation of the Andean cordillera.
The present tectonic framework of South America consists of three fundamental units: the ancient cratons, the relatively recent Andean ranges, and a number of basins. Five cratons—Amazonia, São Francisco, Luis Alves, Alto Paraguay, and Río de la Plata—represent the Precambrian core of South America, and (with the exception of the Alto Paraguay craton) those now appear as upwarped massifs arrayed from north to south in the immense eastern portion of the continent; a number of other Precambrian crustal blocks also were accreted along the margins of South America over geologic time. The lofty ranges and intermontane plateaus of the Andes rise along the entire western margin of the continent and represent the collision in the Cenozoic Era (about the past 66 million years) of the Pacific and South American plates brought about by the opening of the South Atlantic. Finally, vast, downwarped, sediment-filled basins are found between the cratons and along the entire eastern margin of the Andes.
The Precambrian
Precambrian rocks constitute the oldest rocks of the continent and are preserved in the five core cratons. Those rocks are represented by high- to low-grade metamorphosed assemblages along heavily deformed belts of plutonic (intrusive), metavolcanic (metamorphosed extrusive igneous rocks), and metasedimentary rocks. Rocks of Archean age (2.5 to 4 billion years old) are known in the Amazonia, Luis Alves, and São Francisco cratons, although precisely dated rock samples are scarce. Ages older than 3 billion years have been reported in the Imataca Complex of Venezuela and in the Xingu area of Brazil, both in the Amazonia craton. The oldest rocks found so far—with ages of some 3.4 billion years—are in the São Francisco craton in the Brazilian state of Bahia. In the other cratons (e.g., the Río de la Plata craton in Uruguay) the dating of Archean rocks has been inconclusive. Greenstone belts, which are remnants of Archean oceanic crust emplaced in the suture zones (convergent plate boundaries), contain most of South America’s known large gold deposits, such as those located near Belo Horizonte, Brazil. Two major cycles of crustal deformation occurred in the Precambrian, widely separated in time from each other. The first, called the Trans-Amazonian cycle, took place approximately 2.2 to 1.8 billion years ago; and the second, the Brazilian cycle, between about 900 and 570 million years ago.
The Trans-Amazonian cycle
Trans-Amazonian rocks can be subdivided into three distinct groups: orogenic belts, such as the Maroni-Itacaiúnas belt of the Amazonia craton or the Salvador-Juazeiro belt of the São Francisco; stable cover rocks, such as the Chapada Diamantina formation in Bahia or the Carajás and Roraima platform deposits; and large extensional dike swarms (groups of tabular intrusions of igneous rock into sedimentary strata). The orogenic belts represent old mountain chains that had been formed either along the margins of the continent as geosynclines (downwarps of Earth’s crust) and then uplifted, such as the Maroni-Itacaiúnas belt, or were the result of collisions between continental blocks, such as the Tandil belt in Buenos Aires, Argentina.
Such collisions are believed to have formed a supercontinent (sometimes called the first Pangea) some 1.8 billion years ago. The sedimentary cover of that supercontinent (preserved on the Amazonia craton), consisting of postcollision rhyolites and clastic shelf deposits, was deep and widespread and obliterated earlier suture boundaries. Extensive stratified iron and manganese deposits are found in those sequences, such as near Carajás, Brazil. Early phases of continental-plate dispersal produced extensive dike swarms of mafic rock, including a zone some 60 miles (100 km) wide in west-central Uruguay where hundreds of gabbro dikes are now emplaced along a 150-mile (240-km) stretch.
The Brazilian cycle
Rocks of the Brazilian cycle today are manifested in a series of orogenic belts—developed mainly on previously deformed continental crust—that were formed during the amalgamation of the Precambrian cratons into the first supercontinent in late Proterozoic time (about 1 billion to 541 million years ago). Most of present-day South America, encompassing the platforms of Brazil, Guyana, and southern Venezuela, was accreted at that time—together with Africa—to form the western part of the huge southern supercontinent of Gondwana; Precambrian blocks that were not part of Gondwana—notably the Santa Marta Massif in Colombia, the Arequipa block in Peru, and Patagonia in Argentina—were accreted later during Paleozoic times.
The Brasilides in the southern Brazilian state of Mato Grosso represent the type locality of the Brazilian orogenic cycle. There, important sequences of green schists, platform limestones, and quartzites, as well as red bed molasse formations (associated with granitoids), permit a reconstruction of the collision between the Amazonia craton’s passive (i.e., without active volcanoes) margin and the Alto Paraguay craton’s active margin (now partially covered by the Paraná River basin). The interpreted suture zone between the two cratons corresponds to the Paraguay-Araguaia line, along which mafic and ultramafic rocks are found today.
Several other Brazilian belts are known, such as the structurally complex Borborema belt and the Dom Feliciano belt in southern Brazil and Uruguay, which resulted from the collision between the Río de la Plata craton and the Kalahari craton of present-day Africa. The Dom Feliciano belt represents a complex suture zone where rocks typical of a late Proterozoic arc system were trapped between the two cratons; those rocks were then covered by plateaus of rhyolites during the early Cambrian Period (about 541 million years ago). A striking coincidence exists between that suture, which is known as the Brazilian–Pan-African suture, and the inception of the future rift system that opened the Atlantic Ocean. The Pampean Sierras in Argentina are a good example of a Brazilian belt formed by accretion of an island-arc system and several small continental plates.