Geology of the Rocky Mountains

The Geology of the Rocky Mountains reveals a discontinuous series of mountain ranges with distinct geological origins. Collectively these make up the Rocky Mountains, a majestic barrier that stretches from Canada through central New Mexico.

The Rocky Mountains took shape during a period of intense plate tectonic activity that formed much of the rugged landscape of the western United States. Three major mountain-building episodes reshaped the west from about 170 to 40 million years ago (mya) in the Jurassic to the Cenozoic periods. The Laramide orogeny, about 70-40 million years ago, was the last of the three episodes and was responsible for raising the Rocky Mountains.cite web |url=http://wrgis.wr.usgs.gov/docs/parks/province/rockymtn.html|title=Geologic Provinces of the United States: Rocky Mountains|accessdate=2006-12-10|format=HTML|work=USGS Geology in the Parks (public domain source)]

The Ancestral Rocky Mountains

The Ancestral Rocky Mountains were an ancient Paleozoic mountain range that existed in western North America in the location of the present-day southern Rocky Mountains in Colorado. The range was formed approximately 300 mya during the Pennsylvanian. At the time of the uplift, western North America in the area of present-day Colorado was largely covered by a shallow sea. The uplift created two large mountainous islands, known to geologists as Frontrangia and Uncompahgria, located roughly in the current locations of the Front Range and the San Juan Mountains. They consisted largely of Precambrian metamorphic rock forced upward through layers of limestone laid down in the shallow sea throughout the early and late Paleozoic. [cite book|title=Roadside Geology of Colorado|last=Chronic|first=Halka|year=1980]

The mountains eroded throughout the late Paleozoic and early Mesozoic, leaving a large deposition of debris in the surrounding floodplains that formed layers of sedimentary rock.

Before the Laramide orogeny

During the last half of the Mesozoic Era, the Age of the Dinosaurs, much of today's California, British Columbia, Oregon, and Washington were added to North America. Western North America suffered the effects of repeated collision as slabs of ocean crust sank beneath the continental edge. Slivers of continental crust, carried along by subducting ocean plates, were swept into the subduction zone and scraped onto North America's edge.

These terranes represent a variety of tectonic environments. Some are ancient island arcs, similar to Japan, Indonesia and the Aleutians, others are fragments of oceanic crust obducted onto the continental margin while others represent small isolated mid oceanic islands.

Magma generated above the subducting slab rose into the North American continental crust about 200-300 miles inland. Great arc-shaped volcanic mountain ranges, known as the Sierran Arc, grew as lava and ash spewed out of dozens of individual volcanoes. Beneath the surface, great masses of molten rock were injected and hardened in place.

Mesozoic deposition in the Rockies was a mix of marine, transitional, and continental that varied over time as crustal conditions altered the region. By the close of this era, 10,000 to 15,000 feet (3000 to 4500 m) of sediment accumulated in 15 recognized formations. The most extensive non-marine formations were deposited in the Cretaceous period when the eastern part of the Cretaceous Seaway covered the region. The sediment for those formations came from rock eroded from a mountain chain east of the seaway interbeded with ash from volcanos west of the seaway in the Sierran Arc.

For 100 million years the effects of plate collisions were focused very near the edge of the North American plate boundary, far to the west of the Rocky Mountain region. It was not until 70 mya that these effects began to reach the Rockies.

Raising the Rockies

The growth of the Rocky Mountains has been one of the most perplexing of geologic puzzles. Mountain building is normally focused between 200 to 400 miles inland from a subduction zone boundary. Geologists continue to gather evidence to explain the rise of the Rockies so much farther inland; the answer most likely lies with an unusual subducting slab.

At a typical subduction zone, an oceanic plate typically sinks at a fairly high angle, and a volcanic arc grows above the subducting plate. During the growth of the Rocky Mountains, the angle of the subducting plate may have been significantly flattened, moving the focus of melting and mountain building much farther inland than is normally expected. It is postulated that the shallow angle of the subducting plate greatly increased the friction and other interactions with the thick continental mass above it. Tremendous thrusts piled sheets of crust on top of each other, building the extraordinarily broad, high Rocky Mountain range.

The current Rockies were forced upwards through the layers of Pennsylvanian and Permian sedimentary remnants of the Ancestral Rocky Mountains. Such sedimentary remnants were often tilted at steep angles along the flanks of the modern range and visible in many places throughout the Rockies, included prominently along the Dakota Hogback, an early Cretaceous sandstone formation that runs along the eastern flank of the modern Rockies.

References

External links

* [http://academic.emporia.edu/aberjame/field/rocky_mt/rocky.htm Southern Rockies Geology]