The Rockies are typically diverse. The Southern Rockies are composed of a disconnected series of lofty elongated upwarps, their cores made of granitic basement rocks, stripped of sediments, and heavily glaciated at high elevations. In New Mexico and along the western flanks of the Colorado ranges, widespread volcanism and deformation of colourful sedimentary rocks have produced rugged and picturesque country, but the characteristic central Colorado or southern Wyoming range is impressively austere rather than spectacular. The Front Range west of Denver is prototypical, rising abruptly from its base at about 6,000 feet (1,825 metres) to rolling alpine meadows between 11,000 and 12,000 feet (3,350 and 3,650 metres). Peaks appear as low hills perched on this high-level surface, so that Colorado, for example, boasts 53 mountains over 14,000 feet (4,270 metres) but not one over 14,500 feet (4,420 metres).
The Middle Rockies cover most of west-central Wyoming. Most of the ranges resemble the granitic upwarps of Colorado, but thrust faulting and volcanism have produced varied and spectacular country to the west, some of which is included in Grand Teton and Yellowstone national parks. Much of the subregion, however, is not mountainous at all but consists of extensive intermontane basins and plains—largely floored with enormous volumes of sedimentary waste eroded from the mountains themselves. Whole ranges have been buried, producing the greatest gap in the Cordilleran system, the Wyoming Basin—resembling in geologic structure and topography an intermontane peninsula of the Great Plains. As a result, the Rockies have never posed an important barrier to east–west transportation in the United States; all major routes, from the Oregon Trail to interstate highways, funnel through the basin, essentially circumventing the main ranges of the Rockies.
Grand Teton National Park: Teton RangeThe Teton Range at sunset, with Jenny Lake in the foreground, Grand Teton National Park, northwestern Wyoming, U.S.Robert Glusic/Getty Images
The Northern Rockies contain the most varied mountain landscapes of the Cordillera, reflecting a corresponding geologic complexity. The region’s backbone is a mighty series of batholiths—huge masses of molten rock that slowly cooled below the surface and were later uplifted. The batholiths are eroded into rugged granitic ranges, which, in central Idaho, compose the most extensive wilderness country in the conterminous United States. East of the batholiths and opposite the Great Plains, sediments have been folded and thrust-faulted into a series of linear north–south ranges, a southern extension of the spectacular Canadian Rockies. Although elevations run 2,000 to 3,000 feet (600 to 900 metres) lower than the Colorado Rockies (most of the Idaho Rockies lie well below 10,000 feet [3,050 metres]), increased rainfall and northern latitude have encouraged glaciation—there as elsewhere a sculptor of handsome alpine landscape.
The western branch of the Cordillera directly abuts the Pacific Ocean. This coastal chain, like its Rocky Mountain cousins on the eastern flank of the Cordillera, conceals bewildering complexity behind a facade of apparent simplicity. At first glance the chain consists merely of two lines of mountains with a discontinuous trough between them. Immediately behind the coast is a line of hills and low mountains—the Pacific Coast Ranges. Farther inland, averaging 150 miles (240 km) from the coast, the line of the Sierra Nevada and the Cascade Range includes the highest elevations in the conterminous United States. Between these two unequal mountain lines is a discontinuous trench, the Troughs of the Coastal Margin.
The apparent simplicity disappears under the most cursory examination. The Pacific Coast Ranges actually contain five distinct sections, each of different geologic origin and each with its own distinctive topography. The Transverse Ranges of southern California are a crowded assemblage of islandlike faulted ranges, with peak elevations of more than 10,000 feet but sufficiently separated by plains and low passes so that travel through them is easy. From Point Conception to the Oregon border, however, the main California Coast Ranges are entirely different, resembling the Appalachian Ridge and Valley region, with low linear ranges that result from erosion of faulted and folded rocks. Major faults run parallel to the low ridges, and the greatest—the notorious San Andreas Fault—was responsible for the earthquake that all but destroyed San Francisco in 1906. Along the California–Oregon border, everything changes again. In this region, the wildly rugged Klamath Mountains represent a western salient of interior structure reminiscent of the Idaho Rockies and the northern Sierra Nevada. In western Oregon and southwestern Washington the Coast Ranges are also different—a gentle, hilly land carved by streams from a broad arch of marine deposits interbedded with tabular lavas. In the northernmost part of the Coast Ranges and the remote northwest, a domal upwarp has produced the Olympic Mountains; its serrated peaks tower nearly 8,000 feet (2,440 metres) above Puget Sound and the Pacific, and the heavy precipitation on its upper slopes supports the largest active glaciers in the United States outside of Alaska.
South Fork Kings River, Kings Canyon National Park, California, U.S.Josef Muench
East of these Pacific Coast Ranges the Troughs of the Coastal Margin contain the only extensive lowland plains of the Pacific margin—California’s Central Valley, Oregon’s Willamette River valley, and the half-drowned basin of Puget Sound in Washington. Parts of an inland trench that extends for great distances along the east coast of the Pacific, similar valleys occur in such diverse areas as Chile and the Alaska panhandle. These valleys are blessed with superior soils, easily irrigated, and very accessible from the Pacific. They have enticed settlers for more than a century and have become the main centres of population and economic activity for much of the U.S. West Coast.
Still farther east rise the two highest mountain chains in the conterminous United States—the Cascades and the Sierra Nevada. Aside from elevation, geographic continuity, and spectacular scenery, however, the two ranges differ in almost every important respect. Except for its northern section, where sedimentary and metamorphic rocks occur, the Sierra Nevada is largely made of granite, part of the same batholithic chain that creates the Idaho Rockies. The range is grossly asymmetrical, the result of massive faulting that has gently tilted the western slopes toward the Central Valley but has uplifted the eastern side to confront the interior with an escarpment nearly two miles high. At high elevation glaciers have scoured the granites to a gleaming white, while on the west the ice has carved spectacular valleys such as the Yosemite. The loftiest peak in the Sierras is Mount Whitney, which at 14,494 feet (4,418 metres) is the highest mountain in the conterminous states. The upfaulting that produced Mount Whitney is accompanied by downfaulting that formed nearby Death Valley, at 282 feet (86 metres) below sea level the lowest point in North America.
Mount Whitney, California.© Index Open
The Cascades are made largely of volcanic rock; those in northern Washington contain granite like the Sierras, but the rest are formed from relatively recent lava outpourings of dun-coloured basalt and andesite. The Cascades are in effect two ranges. The lower, older range is a long belt of upwarped lava, rising unspectacularly to elevations between 6,000 and 8,000 feet (1,825 and 2,440 metres). Perched above the “low Cascades” is a chain of lofty volcanoes that punctuate the horizon with magnificent glacier-clad peaks. The highest is Mount Rainier, which at 14,410 feet (4,392 metres) is all the more dramatic for rising from near sea level. Most of these volcanoes are quiescent, but they are far from extinct. Mount Lassen in northern California erupted violently in 1914, as did Mount St. Helens in the state of Washington in 1980. Most of the other high Cascade volcanoes exhibit some sign of seismic activity.