MOUNT MAZAMA is a volcano in the
Mazama's summit was destroyed by a volcanic eruption that occurred around 5677 BC, ± 150 years. The eruption reduced Mazama's approximate 12,000-foot (3,700 m) height by about 1 mile (1,600 m). Much of the volcano fell into the volcano's partially emptied neck and magma chamber . At 8,159 feet (2,487 m), Hillman Peak is now the highest point on the rim.
* 1 History * 2 Name
* 3 Geology
* 3.1 Growth phase
* 4 See also * 5 Notes * 6 References
The Klamath Native Americans of the area believed that the mountain was inhabited by Llao , their god of the underworld . After the mountain destroyed itself the Klamaths recounted the events as a great battle between Llao and his rival Skell, their sky god.
Much of what is known of Mazama's geology comes from a study by Howel
Williams of the
University of California, Berkeley
Mazama started to grow around 400,000 years ago in the
Cone building eruptions lasted until around 50,000 years ago when andesite lava flowed down Mazama's north and southwest slopes. Relatively few of the cone building eruptions issued from the same vent, resulting in a highly complex, approximately 11,000-foot (3,400 m) structure made of overlapping composite cones and shield volcanoes. Consequently, Mazama's base was broader and its sides not as steep as today's Mount Shasta .
After its cone building phase, Mazama lavas became increasingly silica -rich and viscous - two conditions that tend to trap explosive gases . The first major eruption in this new cycle of Mazama's life occurred about 10,000 years later, when dacite flows high on the volcano's southwest face formed a series of domes. These structures were subsequently destroyed by either collapse or steam explosions (see phreatic eruption ). Either way, their destruction created large landslides that left deposits at the head of Munson Valley and as far away as Devils Backbone .
Mazama's next major eruptive period occurred between 25,000 and 30,000 years ago and extruded rhyodacite lava (which has a higher silica content than dacite). These thick, slow moving, pasty flows erupted from a vent on Mazama's northeast flank and solidified to form 600-foot (180 m) high Redcloud Cliff (later cut in two by caldera subsidence) and a dome above what today is Steel Bay.
The volcano then went dormant for roughly the next 20,000 years, while successive ice age glaciers (probably as thick as 1,000 feet (300 m) in troughs) cut large valleys into the mountain's sides. One of the largest glaciers flowed down Munson Valley near the present location of park headquarters, down Annie Creek Valley , and perhaps as far as Fort Klamath . When the last ice age ended 12,000 years ago, those glaciers retreated upslope past the elevation of the current caldera's rim. While Mazama slept, its magma chamber was going through some differentiation, with lighter, more gas- and silica-rich rocks collecting closer to the surface.
Around 5677 BC Mazama awoke from its slumber with explosive rhyodacite eruptions on the northern part of the main summit where Llao Rock now resides. Great quantities of pumice and ash were ejected as a large crater was excavated by the explosions. The tephra was carried by prevailing winds to the east and southeast. Associated with this was a pyroclastic flow that was 1.25 mi (2.0 km) wide, 1,200 feet (370 m) thick at its deepest point, and contained 0.25 cu mi (1.0 km3) of material (later, caldera forming subsidence cut the partially filled crater in two, exposing it in cross section—today this is called Llao Rock).
One to two hundred years later (based on radiocarbon dating ) the last major eruption before the caldera was formed, the Cleetwood flow occurred. This rhyodacite lava flow erupted from a vent near what is now the north caldera rim. The Cleetwood flow was still fluid when the caldera was formed, so it must have erupted just weeks to months beforehand. When Mazama later collapsed into itself, some of the Cleetwood lava backflowed into the caldera.
Mazama's final act started with a large eruption that sent a mile (1.6 km) wide column of hot tephra 5 to 10 miles (8.0 to 16.1 km) into the sky at almost twice the speed of sound . The column collapsed in a series of pyroclastic flows that covered much of the area between and downslope of Llao Rock and Redcloud Cliff. This flow, the first of many, was so hot that it solidified as a welded tuff called the Wineglass Welded Tuff. Flow after flow followed in rapid succession, stressing the ability of Mazama's magma chamber to recharge. The mountain started to sag under its own weight. Concentric ring fractures formed around the volcano, creating convenient conduits for additional volcanic vents.
The eruption entered its final and most destructive cycle with very large and erosive pyroclastic flows erupting from ring fractures all around the volcano. These flows moved out in all directions from Mazama, following river valleys and in some cases not coming to rest for 40 miles (64 km). As the eruptions were occurring Mazama was imploding.
The collapse and the erosive ring eruptions fed each other—the sinking volcano pushed magma upward and the erupting material both lubricated the downward subsidence and eroded the sides, making it easier for much of Mazama to sink into the earth . Also, the sudden and dramatic reduction in pressure on the remaining gas charged molten rock in the magma chamber caused it to react by immediately exploding into a super-heated mix of liberated gases and various grades of pulverized and often frothy lava known as a pyroclastic flow. The force of the explosion pulverized previously solidified rock that happened to be nearby or that recently fell into the caldera from the collapse.
Half of 70,000-year-old Hillman Peak was blown away, exposing the cone in cross section. Many glacier-cut canyons were beheaded and now stand as notches in the caldera rim. Notable among these are Kerr Notch, Munson Valley, and Sun Notch.
The last pyroclastic flow of this stage was andesitic scoria , indicating that Mazama was drawing on material deep from within its magma chamber. This layer of material now forms a dark band in ash layers associated with this eruption cycle (it also created the Pumice Desert ). A last few dying gasps in the form of a series of relatively weak explosions then deposited a well-bedded layer of pumice lapilli and crystal -rich ash up to 50 feet (15 m) thick on the newly formed caldera rim.
In the end an estimated 11 to 14 cu mi (46 to 58 km3) of magma escaped from Mazama's magma chamber during this eruptive cycle as approximately 25 cu mi (100 km3) of tephra (magma is compact due to high pressure surrounding it), qualifying the eruption as a VEI 7 event. The magma was replaced by about the same volume of material when most of Mazama fell into its caldera. At that time, Mazama was about 1 mile (1,600 m) shorter than its initial height of approximately 12,000 feet (3,700 m).
Hundreds of square kilometers of the surrounding countryside were
covered by material ejected from the collapse and associated
eruptions. One pyroclastic flow traveled 40 miles (64 km) from Mazama
Geologists know the exact chemical composition of this tephra (which they call Mazama Ash ) and both geologists and archeologists use the distinctive layer it formed in the specific techniques of relative dating called tephrochronology . As with all tephra layers , Mazama ash is thickest near its source (20 feet (6.1 m)) and becomes thinner with increasing distance from its source. 70 miles (110 km) northwest it is 1 foot (30 cm) thick.
Deposits of pyroclastic flow material near Mazama remained extremely hot for months, and in some places they were more than 250 feet (76 m) deep. Hot gases escaping from the cooling deposits tended to follow vertical channels and emerged at the surface as fumaroles . Over time these gases cemented the channels, which are now exposed as very tall vertical columns and spires of tuff (good examples are along the upper walls of Sand Creek Canyon and Annie Canyon ).
All volcanic activity on Mazama since its collapse has been within the caldera. The first significant eruptive period of this phase created an andesite lava platform (the 'central platform') that rises 1,200 feet (365 m) above the caldera floor. Later eruptions created cinder cones such as Wizard Island (c. 6,000 years old and 763 feet (233 m) high) and Merriam Cone and also rhyodacite domes (most of these features are under water).
Over time much of the approximate 4,000-foot (1,200 m) depth of the
caldera was filled with volcanic material. Part of the remainder was
filled with water from snowmelt and rain to eventually form Crater
Aerial view of Crater Lake. *
This article includes a list of references , but ITS SOURCES REMAIN UNCLEAR because it has INSUFFICIENT INLINE CITATIONS . Please help to improve this article by introducing more precise citations. (February 2013) (Learn how and when to remove this template message )
* ^ A B C D E "Crater Lake".
Global Volcanism Program . Smithsonian
Institution . Retrieved 2008-12-20.
* ^ "Mount Mazama".
Geographic Names Information System
* Harris, Stephen L. (2005). Fire Mountains of the West: The Cascade
and Mono Lake Volcanoes (3rd ed.).
* v * t * e
* v * t * e
BASIN AND RANGE
* v * t * e
Comfort Station No. 68
Comfort Station No. 72
* v * t * e
Native peoples of
Central Kalapuya language
* Native American peoples of
* v * t * e
Early history of
* Bridge of the Gods
1700 Cascadia earthquake
William Robert Broughton
* Native peoples history * History to 1806 * Pioneer history * Moder