РефератыИностранный языкLaLateral Blast Essay Research Paper Lateral Blast

Lateral Blast Essay Research Paper Lateral Blast

Lateral Blast Essay, Research Paper


Lateral Blast The sudden


removal of the volcano’s north flank released pressure on the hydrothermal and magmatic system within the volcano,


triggering a devastating lateral blast to the north. The abrupt pressure


release, or "uncorking," of the volcano by the avalanche can be


compared in some ways to the removal of the cap from a vigorously shaken bottle


of soda pop, or to punching a hole in a boiler tank under high pressure. The


northward-directed lateral blast of rock, ash,


and hot gas devastated an area of about 150 square miles. The blast stripped trees from most hill slopes


within six miles north of the volcano and leveled nearly all vegetation for as


far as 13 miles in a 180-degree arc north of the mountain. The blast deposited


blocks and smaller rock fragments and organic debris over the devastated area


in layers to more than three feet in thickness. Surrounding this zone of


toppled vegetation is a narrow band of scorched but standing timber in which sandy deposits


are as thick as four inches; this zone has an area of about 25 square miles. The Eruption A


magnitude 5.1 earthquake on May 18 (8:32 a.m. PDT) shook loose the steepened


bulge on the volcano’s north flank,


resulting in the largest known landslide in historic time, 2.3 cubic km (0.56


cubic miles). The entire north flank was described by an aerial observal as


"rippling" and "churning" moments before "the north


side of the summit began sliding north along a deep-seated slide plane." As the avalanche reached the north base of the


cone, the topography it encountered caused it to be divided into three


sections: 1.


Part of the


avalanche slid into Spirit Lake, raising the lake bed roughly 180 feet, and


damming its natural outlet. Water displaced by the avalanche surged up the


surrounding hillslopes, washing the blown-down


timber from the lateral blast into the lake. 2.


Part of the


avalanche "ramped" up and over a 1,200 foot high ridge five miles


north of the volcano (Johnston Ridge) depositing debris on top of the ridge and


in the South Colwater Creek drainage. 3.


The bulk of


the avalanche was deflected westward down the North Fork of the Toutle River


valley. The front of the avalanche traveled a distance of 15 miles in about 10


minutes. The resulting deposit covers the valley floor to an average depth of


150 feet, but it is more than 500 feet deep in a few places (such as 1.5 miles


west of Harry Truman’s Lodge). The hummocky avalanche deposit covers a


total area of about 24 square miles. It consists of intermixed volcanic debris


of various sizes, including blocks, pebbles, sand and silt, and blocks of


glacial ice. Mount Saint Helens: The Great Eruption Anonymous


Teacher/Mentor: Rene Dolbec Mount Saint Helens is located in Southern Washington.


Before May 18, 1980 the mountain stood still and was silient and beautiful. Mt.


St. Helens is a composite cone, also called stratovolcanoes which are very


large. These types of volcanoes consists of layers of both lava and cinder. The


layers of lava causes the volcanoes to be mo

re resistant to erosion. Andesite


lava is more "sticky" than basalt and tends to be more explosive. The


first recorded eruption of the mountain was estimated around 40,000 years ago.


In 1802 A.D. there was a great eruption of ash. About this time mudflows and


lava flows occurred. On May 18, 1980 around 8:31 a.m.


Mount Saint Helens erupted. Denver Nelson predicted that the eruption would


occur at 8:30 Sunday morning, and missed his prediction by one minute.


Seventeen missing people were presumably said to be dead from being s o close


to the mountain. Including one eighty year old man who refused to leave his


home, which he had lived in for fifty years, on the side of Mt. St. Helens.


Thinking that he knew the mountain so well that it would never hurt him. But he


was wrong. His memorial would be one everyone at that time would remember. On July 22 two months after the eruption,


the mountain sends plume high into the sky. After the big eruption, the


northern side of Mt. St. Helens was said to look like the surface of the moon.


It was gray and lifeless. When the warm weather started to come, you could


start to see touches of green among the grays and brown. Some small animals


such as chipmunks, white-footed deer mice, and red squirrels had survived under


the snow pack or below the ground. Hundred years from now, a new forest will be


g rowing on the north slope of Mount Saint Helens. Everything that lived on the


mountain before May 18, 1980, will be able to live there again.It depends on what and where you


are talking about. For example, there are many places on Mt. St. Helens that


today still look as bleak as the days after the big eruption. These tend to be


the locations closer to the volcano. On the other hand there are areas that


were covered by quite thick blankets of ash and debris where the plants have


come back to the point that you could be plunked down in the middle of the


forest and not know that something dramatic had even happened. In general, the areas on the edges


of the devastated zones are coming back the fastest because there are sources


of seeds and animals in the adjacent un-devastated zones. The hunting and


fishing industry in and around Spirit Lake has not recovered at all. Volcanologists are getting much


better at predicting eruptions. Several methods are used to monitor volcanoes. These methods are


applied to volcanoes that have shown signs of unrest. The past behavior of the


volcano would provide the best estimate of the potential volume of future


eruptions. Volcanoes erupt because of pressure caused by gas dissolved in the


magma. Different size eruptions are caused by the volume of the magma, magma


supply rate, eruption frequency, composition of magma, size of the conduit, and


gas content. Mount St. Helens was explosive because the magma was viscous


(sticky) and the gas could not escape until it was in the throat of the


volcano. Then the gas expanded and blew the lava into ash-sized fragments.


Sorry, I have not seen "joe vs the volcano" but I hear it is funny.


Most movies (and some TV shows) dont worry much about the accuracy of the


science information – they just want it to be exciting.

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