Western Cordillera
- Also known as:
- North American Cordillera or Pacific Cordillera
Western Cordillera, in western North America, a system of mountain ranges extending from the U.S. state of Alaska through northwestern Canada, the western United States, and into Mexico. The largest range is the Canadian Rockies; others include the Rocky Mountains, the Sierra Nevada, the Cascades, and the Coast Ranges. The continent’s youngest mountains, they are in many places very high and rugged.
Most of the Western Cordillera was built between about 170 million and 40 million years ago when lithospheric plates converged with North America at rapid rates of many tens to more than 100 millimetres (4 inches) per year. The Juan de Fuca Plate is the last remnant of one of these plates. The others have been subducted beneath western North America and have completely disappeared. Thus, in Mesozoic and Early Cenozoic times, an Andean margin similar to that which presently bounds the west coast of South America bounded western North America.
The Coast Ranges of central and northern California, Oregon, and Washington consist of folded and faulted slices of oceanic crust and its overlying sedimentary rocks. Much of the rock that constitutes these mountains was scraped off the oceanic lithosphere at the trench just west of the continent. The Olympic Mountains in northwestern Washington, for instance, consist largely of off-scraped seamounts. The rock of such coastal mountains was intensely deformed and metamorphosed before being elevated to produce the present range. Specifically, the hard basalt that makes up much of the oceanic crust has been metamorphosed into the easily deformed rock serpentinite, which contains the weak, fibrous mineral serpentine. The gentle relief of the Coast Ranges is due in part to the weakness of serpentinite, a characteristic that gives rise to frequent landslides and rapid erosion.
A belt of granite lies inland and forms a mountainous zone from the axis of Baja California (in Mexico), through southern California, along the Sierra Nevada in the states of California and Nevada, northwestward into Idaho, and then north-northwestward along the western margin of the Canadian Rockies to Alaska. This granite belt underlay the volcanoes that marked the subduction zone in Mesozoic and Early Cenozoic times. The intrusion of this granite was most intense between 170 million and 70 million years ago during the Mesozoic Era. The Sierra Nevada of California, which contains Mount Whitney, the highest peak in the contiguous United States, is composed almost entirely of this granite.
While subduction of oceanic lithosphere occurred beneath western North America, a major fold and thrust belt developed east of the granitic belt. During Mesozoic time, the Precambrian basement of Canada and North America was underthrust westward at least 200 km (125 miles) beneath the Andean margin, and the sedimentary rocks covering it were folded and thrust onto one another. Although present in the western United States, this fold and thrust belt is most clearly revealed in the Canadian Rockies along the border between the provinces of Alberta and British Columbia, particularly in Banff and Jasper national parks.
In sum, throughout the latter half of the Mesozoic, from about 170 million to 66 million years ago, the topography of western North America probably resembled that of western South America: a trench lay offshore; a belt of volcanoes underlain by granitic intrusions marked the western edge of a high range of mountains; and a fold and thrust belt lay east of the range. The tectonic history of western North America is more complicated, however, because during this period fragments of both continents and suboceanic plateaus were carried to the subduction zone and collided with North America. Most of the rock now found in westernmost Canada and Alaska consists of separate terrains of rock that were independently accreted to North America and that were subsequently deformed when the next such terrain collided with it. Moreover, tectonic processes occurring during the Cenozoic (since 66 million years ago) have been different from those that occurred earlier and have severely modified the landscape.
Beginning about 70 million to 80 million years ago, the locus of crustal shortening in the United States shifted from the fold and thrust belt, whose remnants now lie along the borders of western Utah and eastern Nevada and of western Wyoming and eastern Idaho, to eastern Utah, Colorado, and central Wyoming. Between about 70 million and 40 million years ago, thrust faulting on the margins of the Front Range in Colorado, the Laramie Mountains and the Wind River Range in Wyoming, and the Uinta Mountains in Utah, among others, allowed the uplift of blocks of Precambrian rock that are now exposed in the cores of these ranges. Together, these intracontinental ranges of block-faulted mountains form most of the Rocky Mountains of the United States.
During roughly the same period, volcanic rocks were erupted and deposited in parts of the Rockies, such as in southwestern Colorado in what are now the San Juan Mountains. The area that now forms the Colorado Plateau, in southern Utah and northern Arizona, underwent only very mild deformation in the form of small faults and folds and apparently lay at relatively low elevation. Sediment derived from the fold and thrust belt to its west and from the Rockies to its north and east was deposited on this relatively stable area. Thus, some 40 million years ago, a high range of mountains lay along the western margin of North America. This range consisted of a volcanic chain along most of its western edge and an eroded fold and thrust belt on its eastern edge. At the latitude of Wyoming, Colorado, and Utah, another belt of mountains, the present-day Rocky Mountains, lay farther east.
The topography of the western United States has been modified extensively by tectonic processes during the last 20 million years. Much of the mountainous terrain of Utah, Nevada, and California underwent large-scale crustal extension, beginning more than 40 million years ago but accelerating about 15 million years ago. The crustal extension approximately doubled the surface area of the region between central Utah and the Sierra Nevada, presumably with a reduction in the mean elevation of the mountains.
The present topography of the Basin and Range Province of North America is a direct manifestation of this crustal extension. The most prominent basins, such as Death Valley and Owens Valley in California, are small rift valleys that were formed during the last few million years. This phase of the crustal extension continues even today, with such basins becoming deeper and the surrounding ranges increasing in height. This condition is readily discernible in the case of Owens Valley and the Sierra Nevada. The occurrence of a major fault on the east side of the Sierras has allowed the valley to drop with respect to the mountain range, which has been tilted up toward the east.
Concurrent with this extension, the uppermost mantle beneath parts of the western United States has become hotter. The considerable height of the Colorado Plateau, for instance, appears to be the result of the warming of the underlying mantle during roughly the past 10 million years. Such mantle heating also seems to have been responsible, at least in part, for the present elevation of much of the Western Cordillera.
The one area where rapid subduction of oceanic lithosphere (more than 50 millimetres [2 inches] per year) has continued is southern Alaska, where the Pacific Plate is being underthrust beneath the coast. The St. Elias Mountains, the tallest in southeastern Alaska and Yukon, appear to be the direct consequences of this convergence and rapid underthrusting. Deformation of the southern Alaskan crust extends northward several hundred kilometres to the Alaska Range, where the highest mountain in North America, Denali (Mount McKinley), is found.
North–south crustal shortening in southern Alaska occurs both by thrust faulting and by strike-slip faulting on nearly vertical, northwesterly trending planes. Denali lies adjacent to one such major strike-slip fault, the Denali Fault. The rocks that make up Denali have been displaced several tens of kilometres northwestward relative to the rocks north of the Denali Fault and a few kilometres upward. This small vertical component, compared with the large horizontal component, has created the high peak.