Tertiary rocks

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Major subdivisions of the Tertiary System

Classically, the Cenozoic Era was divided into the Tertiary and Quaternary periods, separated at the boundary between the Pliocene and Pleistocene epochs (formerly set at 1.8 million years ago); however, by the late 20th century many authorities considered the terms Tertiary and Quaternary to be obsolete. In 2005 the International Commission on Stratigraphy (ICS) decided to recommend keeping the Tertiary and Quaternary periods as units in the geologic time scale but only as sub-eras within the Cenozoic Era. By 2009 the larger intervals (periods and epochs) of the Cenozoic had been formalized by the ICS and the International Union of Geological Sciences (IUGS). The ICS redivided the Cenozoic Era into the Paleogene Period (66 million to 23 million years ago), the Neogene Period (23 million to 2.6 million years ago), and the Quaternary Period (2.6 million years ago to the present). Under this paradigm, the Paleogene and Neogene span the interval formerly occupied by the Tertiary. The Paleogene Period, the oldest of the three divisions, commences at the onset of the Cenozoic Era and includes the Paleocene Epoch (66 million to 56 million years ago), the Eocene Epoch (56 million to 33.9 million years ago), and the Oligocene Epoch (33.9 million to 23 million years ago). The Neogene spans the interval between the beginning of the Miocene Epoch (23 million to 5.3 million years ago) and the end of the Pliocene Epoch (5.3 million to 2.6 million years ago). The Quaternary Period begins at the base of the Pleistocene Epoch (2.6 million to 11,700 years ago) and continues through the Holocene Epoch (11,700 years ago to the present).

Precise stratigraphic positions for the boundaries of the various traditional Tertiary series were not specified by early workers in the 19th century. It is only in more recent times that the international geologic community has formulated a philosophical framework for stratigraphy. By specifying the lower limits of rock units deposited during successive increments of geologic time at designated points in the rock record (called stratotypes), geologists have established a series of calibration points, called Global Boundary Stratotype Sections and Points (GSSPs), at which time and rock coincide. These boundary stratotypes are the linchpins of global chronostratigraphic units—essentially, the points of reference that mark time within the rock—and serve as the point of departure for global correlation.

Several boundary stratotypes have been identified within Tertiary rocks. The Cretaceous-Tertiary, or K-T, boundary has been stratotypified in Tunisia in North Africa. (Increasingly, this boundary is known as the Cretaceous-Paleogene, or K-P, boundary.) Its estimated age is 66 million years. The Paleocene-Eocene boundary has an estimated age of 56 million years; its GSSP is located near Luxor, Egypt. In the early 1990s the Eocene-Oligocene boundary was stratotypically established in southern Italy, with a currently estimated age of approximately 33.9 million years. The Oligocene-Miocene boundary (which also corresponds to the boundary between the Paleogene and Neogene systems) has been stratotyped in Carrosio, Italy; its age has been calculated at roughly 23 million years old. The GSSP associated with the Miocene-Pliocene boundary is located in Sicily and has been dated to about 5.3 million years ago, although the location of this boundary may be repositioned in the future. The boundary between the Pliocene and the Pleistocene, separating the Neogene and Quaternary systems, has been stratotyped in Sicily near the town of Gela and dated to approximately 2.6 million years ago.

Occurrence and distribution of Tertiary deposits

With the exception of the vast Tethys seaway, the basins of western Europe, and the extensive Mississippi Embayment of the Gulf Coast region in the United States, Tertiary marine deposits are located predominantly along continental margins and occur on all continents. Miocene deposits are found as far north as Alaska; Eocene deposits are found in eastern Canada; and Paleocene deposits are located in Greenland. Deposits of Paleogene age occur on Seymour Island near the Antarctic Peninsula, and Neogene deposits containing marine diatoms (silica-bearing marine phytoplankton) have recently been identified intercalated between glacial tills on Antarctica itself.

Global sea levels have fallen gradually by about 300 metres (about 1,000 feet) over the past 100 million years, but superimposed upon that trend is a higher-order series of globally fluctuating increases and decreases (that is, transgressions and regressions) in sea level. These fluctuations vary with a periodicity of several million years; where they have occurred along passive (that is, tectonically stable) continental margins, they have left a record of marginal marine brackish accumulations that overlap with continental sedimentary deposits in Europe, North Africa, the Middle East, southern Australia, and the Gulf and Atlantic coastal plains of North America. In most regions, Paleogene seas extended farther inland than did those of the Neogene. In fact, the most extensive transgression of the Tertiary is that of the Lutetian Age (Middle Eocene), roughly 49 million to 41 million years ago. During that interval, the Tethys Sea expanded onto the continental margins of Africa and Eurasia and left extensive deposits of nummulitic rocks, which are made up of shallow-water carbonates. Sediments of Tertiary age are widely developed on the deep ocean floor and on elevated seamounts as well. In the shallower parts of the ocean (above depths of 4.5 km [about 3 miles]), sediments are calcareous (made of calcium carbonate), siliceous (derived from silica), or both, depending on local productivity. Below 4.5 km the sediments are principally siliceous or inorganic, as in the case of red clay, due to dissolution of calcium carbonate.

Nonmarine Tertiary sedimentary and volcanic deposits are widespread in North America, particularly in the intermontane basins west of the Mississippi River. During the Neogene, volcanism and terrigenous deposition extended almost to the Pacific coast. In South America, thick nonmarine clastic sequences (conglomerates, sandstones, and shales) occur in the mobile tectonic belt of the Andes Mountains and along their eastern front; these sequences extend eastward for a considerable distance into the Amazon basin. Tertiary marine deposits occur along the eastern margins of Brazil and Argentina, and they were already known to English naturalist Charles Darwin during his exploration of South America from 1832 to 1834.