Volcanoes are mountains, but they are very different from other mountains;
they are not formed by folding and
crumpling or by uplift and erosion.
Instead, volcanoes are built by the accumulation of their own eruptive products
--
lava,
bombs (crusted over lava blobs),
ashflows,
and
tephra (airborne ash and dust).
A volcano is most
commonly a conical hill or mountain built around a vent that
connects with reservoirs of molten rock below the
surface of the Earth.
The term volcano also refers to the opening or vent through
which the molten rock and
associated gases are expelled.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication.
The word "volcano" comes from the little island of Vulcano in the
Mediterranean Sea off Sicily.
Centuries ago, the
people living in this area believed that Vulcano was the
chimney of the forge of Vulcan -- the blacksmith of the
Roman gods. They thought that the hot lava fragments and
clouds of dust erupting form Vulcano came from
Vulcan's forge as he beat out thunderbolts for Jupiter,
king of the gods, and weapons for Mars, the god of war.
In Polynesia the people attributed eruptive activity to the
beautiful but wrathful Pele, Goddess of Volcanoes,
whenever she was angry or spiteful.
Today we know that volcanic eruptions are not super-natural but can be
studied and interpreted by scientists.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication.
An eruption occurs when magma rises from its source or from a storage
reservoir and finally reaches the Earth's surface. As it rises, the magma
fractures overlying rocks, which causes earthquakes, and parts of the volcano
deform as magma approaching the surface makes room for itself.
-- From:
Brantley and Topinka, 1984, Earthquake Information Bulletin, v.16, no.2.
More than 80 percent of the Earth's surface -- above and below sea level -- is
of volcanic origin. Gaseous emissions from volcanic vents over hundreds of
millions of years formed the Earth's earliest oceans and atmosphere, which
supplied the ingredients vital to evolve and sustain life. Over geologic eons,
countless volcanic eruptions have produced mountains, plateaus, and plains, which
subsequent erosion and weathering have sculpted into majestic landscapes and
formed fertile soils.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication.
About 500 active volcanoes are known on Earth, not counting those that lie
beneath the sea.
-- From:
Tilling, 1980, Volcanoes: Earthquake Information Bulletin, v.12, n.4.
Volcanoes are not randomly distributed over the Earth's surface. Most are
concentrated on the edges of continents, along island chains, or beneath the sea
forming long mountain ranges. More than half of the world's active volcanoes
above sea level encircle the Pacific Ocean to form the
circum-Pacific "Ring of Fire". -- From:
Brantley, 1994, Volcanoes of the United States: USGS General Interest
Publication.
Scientists have estimated that at least 200,000 persons have lost their
lives as a result of volcanic eruptions during the last 500 years.
Between 1980 and 1990, volcanic activity
killed at least 26,000 people and forced nearly 450,000 to flee from their
homes.
-- From:
Tilling, 1980, Volcanoes: Earthquake Information Bulletin, v.12, n.4,
and
Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
The Earth's crust, on which we live and depend, is in large part the product of
millions of once-active volcanoes and tremendous volumes of
magma
that did not erupt but instead cooled below the surface. Such
persistent and widespread volcanism has resulted in many valuable natural
resources throughout the world. For example, volcanic ash blows over thousands
of square kilometers of land increases soil fertility for forests and
agriculture by adding nutrients and acting as a mulch. Groundwater heated by
large, still-hot magma bodies can be tapped for geothermal energy. And over
many thousands of years, heated groundwater has concentrated valuable minerals,
including copper, tin, gold, and silver, into deposits that are mined throughout
the world.
-- From:
Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
The May 18, 1980 eruption of
Mount St. Helens (Washington)
was the most
destructive in the history of the United States.
Novarupta (Katmai) Volcano , Alaska,
erupted considerably more material in 1912, but owing to the
isolation and sparse population of the region affected, there were no human
deaths and little property damage. In contrast, Mount St. Helens' eruption
in a matter of hours caused loss of lives and widespread destruction of
valuable property, primarily by the
debris avalanche, the
lateral blast, and the
mudflows.
-- From: Tilling et.al., 1990, The Eruptions of Mount St. Helens:
Past, Present, and Future: USGS Information Publication.
Mauna Loa (Hawaii) is the world's largest active volcano, projecting
13,677 feet above sea level, its top being over
28,000 feet above the deep ocean floor.
From its base below sea level to its summit, Mauna Loa is taller than
Mount Everest.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication, and
Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
Though few people in the United States may actually experience an erupting
volcano, the evidence for earlier volcanism is preserved in many rocks of North
America. Features seen in volcanic rocks only hours old are also present in
ancient volcanic rocks, both at the surface and buried beneath younger deposits.
A thick ash deposit sandwiched between layers of sandstone in Nebraska, the
massive granite peaks of the Sierra Nevada mountain range, and a variety of
volcanic layers found in eastern Maine are but a few of the striking clues of
past volcanism.
-- From: Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
The United States ranks third, behind Indonesia and Japan, in the number
of historically active volcanoes (that is, those for which we have written
accounts of eruptions). In addition, about 10 percent of the more than
1,500 volcanoes that have erupted in the past 10,000 years are located
in the United States. Most of these volcanoes are found in the Aleutian
Islands, the Alaska Peninsula, the Hawaiian Islands, and the
Cascade Range of the Pacific Northwest.
-- From: Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
Metropolitan Portland, Oregon,
like Auckland, New Zealand, includes most of a
Plio-Pleistocene volcanic field. The
Boring Lava
includes at least 32 and possibly 50
cinder cones
and small
shield volcanoes.From:
Wood and Kienle, 1990, Volcanoes of North America: United States and Canada:
Cambridge University Press, Contribution by John E. Allen
Several lofty volcanic peaks dominate the
Cascade Range of the Pacific Northwest;
the principal part of the range extends from
Mount Garibaldi
in British Columbia, Canada, to
Lassen Peak
in northern California, a distance of about 1000 miles.
-- From:
Tilling, et.al., 1990, Eruptions of Mount St. Helens: Past, Present, and Future:
USGS General Interest Publication,
and
Preparing for The Next Eruption in the Cascades:
USGS Open-File Report 94-485
Eruptions in the
Cascades
have occurred at an average
rate of 1-2 per century during the last 4000 years, and
future eruptions are certain.
-- From:
Preparing for The Next Eruption in the Cascades:
USGS Open-File Report 94-485
Seven volcanoes in the
Cascades have erupted since the first U.S. Independence Day a
little more than 200 years ago.
-- From:
Preparing for The Next Eruption in the Cascades:
USGS Open-File Report 94-485
Mount Rainier, in Washington State,
is the
tallest (4,392 meters, 14,410 feet) volcano in the Cascade Range but it
is only the third most voluminous volcano after Mounts
Shasta and
Adams
.
-- From:
Swanson, et.al., 1989,
IGC Field Trip T106: Cenozoic Volcanism in the Cascade Range and
Columbia Plateau, Southern Washington and Northernmost Oregon:
American Geophysical Union Field Trip Guidebook T106, p.8.
Mount Garibaldi
(British Columbia, Canada) is a
composite cone and
domes built on a glacier.
It is one of the larger volcanoes (6.5 cubic kilometers) in
a chain of small Quaternary volcanic piles -- the Garibaldi Belt --
within the southern Coast Mountains of British Columbia.
Mount Garibaldi is noteworthy both for the excellent exposures of its internal
structure and for its striking topographic anomalies, which can be attributed to
the growth of the volcano onto a major glacial stream, part of the Cordilleran
Ice Sheet, and the subsequent collapse of the flanks of the volcano with the
melting of the ice.
-- From:
Wood and Kienle, 1990, Volcanoes of North America: United States and Canada:
Cambridge University Press, 354p., p.144-145,
Contribution by William H. Mathews
Mount Rainier
(Washington) at 14,410 feet (4,393 meters),
the highest peak in the
Cascade Range,
is a dormant volcano whose load of
glacier ice exceeds that of any other
mountain in the conterminous United States.
Mount Rainier has 26
glaciers containing more than five times as much snow and ice as all the
other Cascade volcanoes combined.
Mount Baker
(Washington) at 10,778 feet (3,285 meters),
is an ice-clad volcano in the North Cascades of
Washington State about 31 miles
due east of the city of Bellingham.
After Mount Rainier, it is the most
heavily glaciated of the Cascade volcanoes: the
volume of snow and ice on Mount Baker
(about 1.8 cubic kilometers; 0.43 cubic mile)
is greater than that
of all the other Cascades volcanoes
(except Rainier) combined.
-- From:
Hoblitt, et.al., 1995,
Volcano hazards from Mount Rainier, Washington:
USGS Open-File Report 95-273,
Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication,
and
Gardner, et.al., 1995,
Potential Volcanic Hazards from Future Activity of Mount Baker,
Washington:
USGS Open-File Report 95-498.
Although
Mount Rainier
(Washington)
has not produced a significant eruption in the past 500 years, it
is potentially the most dangerous volcano in the
Cascade Range
because of its great height, frequent
earthquakes,
active
hydrothermal system,
and extensive
glacier mantle.
Mount Rainier has 26
glaciers containing more than five times as much snow and ice as all the
other Cascade volcanoes combined. If only a small part of this ice were melted
by volcanic activity, it would yield enough water to trigger enormous
lahars.
Mount Rainier's potential for generating destructive mudflows is
enhanced by its great height above surrounding valleys.
-- From:
Scott, et.al., 1990, Sedimentology, Behavior, and Hazards of Debris Flows at
Mount Rainier, Washington: USGS Open-File Report 90-385, and
Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
Debris flows
pose the greatest hazard to people near
Mount Rainier.
A debris flow is a mixture of mud and rock debris that looks
and behaves like flowing concrete. Giant debris flows sometimes develop when
large masses of weak, water-saturated rock slide from the volcano's flanks.
Many of these debris flows cannot be predicted and may even occur independently
of a volcanic eruption. Giant debris flows can also form during an eruption as
hot rock fragments tumble down the volcano's slopes, eroding and melting snow
and glacier ice. Although they happen infrequently, giant debris flows have the
potential to inundate much of the southern Puget Sound lowland. Scientists
estimate that debris flows can travel the distance between Mount Rainier and the
Puget Sound lowland in as little as 30 minutes to a few hours. About 100,000
people now live in areas that have been buried by debris flows during the past
few thousand years.
-- From: Walder and Driedger, 1995, Living With a Volcano in Your Backyard -
Volcanic Hazards at Mount Rainier: USGS Open-File Report 95-421.
During the past 10,000 years, about 60 giant
debris flows
from
Mount Rainier
have filled river valleys to a depth of hundreds of feet near
the volcano, and have buried the land surface under many feet of mud and rock
sixty miles downstream. Seven debris flows large enough to reach Puget Sound
have occurred in the past 6,000 years.
-- From: Walder and Driedger, 1995, Living With a Volcano in Your Backyard -
Volcanic Hazards at Mount Rainier: USGS Open-File Report 95-421.
Eruptions of
Mount Rainier
usually produce much less
volcanic ash
than do eruptions at
Mount St. Helens.
However, owing to the volcano's great height and
widespread cover of snow and glacier ice, eruption-triggered
debris flows
at Mount Rainier are likely to be much larger -- and will
travel a greater distance -- than those at Mount St. Helens in 1980.
Furthermore, areas at risk from debris flows from Mount Rainier are more densely
populated than similar areas around Mount St. Helens.
-- From: Walder and Driedger, 1995, Living With a Volcano in Your Backyard -
Volcanic Hazards at Mount Rainier: USGS Open-File Report 95-421.
The eruptive history of
Mount St. Helens (Washington)
began about 40,000 years ago with
dacitic volcanism, which continued intermittently until about 2,500 years ago.
This activity included numerous explosive eruptions over periods of hundreds to
thousands of years, which were separated by apparent dormant intervals ranging
in length from a few hundred to about 15,000 years. The range of rock types
erupted by the volcano changed about 2,500 years ago, and since then Mount St.
Helens repeatedly has produced lava flows of andesite, and on at least two
occasions, basalt. Other eruptions during the last 2,500 years produced dacite
and andesite
pyroclastic flows
and
lahars,
and dacite, andesite, and basalt
airfall tephra.
... Major dormant intervals of the last 2,500 years range in
length from about 2 to 7 centuries.
-- From:
Mullineaux and Crandell, 1981, The Eruptive History of Mount St. Helens:
IN: The 1980 Eruptions of Mount St. Helens, Washington: USGS Professional Paper
1250.
Some Indians of the Pacific Northwest variously called
Mount St. Helens (Washington)
"Louwala-Clough," or "smoking mountain." The modern name, Mount St. Helens,
was given to the volcanic peak in 1792 by Captain George Vancouver of the
British Royal Navy, a seafarer and explorer. He named it in honor of a fellow
countryman, Alleyne Fitzherbert, who held the title Baron St. Helens and who was
at the time the British Ambassador to Spain. Vancouver also named three other
volcanoes in the Cascades --
Mounts Baker,
Hood, and
Rainier --
for British naval officers.
-- From:
Tilling, et.al., 1990, Eruptions of Mount St. Helens: Past, Present, and Future:
USGS General Interest Publication.
Before May 18, 1980,
Mount St. Helens'
summit altitude of 9,677 feet made it only the fifth highest peak in
Washington State. It stood out handsomely, however, from surrounding hills
because it rose thousands of feet above them and had a perennial cover of ice
and snow. The peak rose more than 5,000 feet above its base, where the
lower flanks merge with adjacent ridges. On
May 18, 1980,
the volcano
lost an estimated 3.4 billion cubic yards (0.63 cubic mile) of its cone
(about 1,300 feet in height), leaving behind a horseshoe-shaped crater (open
to the north), with the highest part of the crater rim on the
southwestern side being at 8,365 feet elevation.
-- From:
Foxworthy and Hill, 1982, Volcanic Eruptions of 1980 at Mount St. Helens,
The First 100 Days: USGS Professional Paper 1249.
During the 9 hours of vigorous
eruptive activity,
about 540 million tons of ash
fell over an area of more than 22,000 square miles. Tot total volume of the ash
before its compaction by rainfall was about 0.3 cubic mile, equivalent to an
area the size of a football field piled about 150 miles high with fluffy ash.
-- From:
Tilling et.al., 1990, The Eruptions of Mount St. Helens: Past, Present, and
Future: USGS General Interest Publication.
The
May 18, 1980
eruptive column at
Mount St. Helens
fluctuated in height through the day, but the eruption subsided by late
afternoon. By early May 19, the eruption had stopped. By that time the
ash cloud
had spread to the central United States. Two days later, even though
the ash cloud had become more diffuse, fine ash was detected by systems used to
monitor air pollution in several cities of the northeastern United States. Some
of the ash drifted around the globe within about 2 weeks.
-- From:
Tilling et.al., 1990, The Eruptions of Mount St. Helens: Past, Present, and
Future: USGS General Interest Publication.
Mount Hood,
3428 meters high,
is the fourth highest peak in the Cascades and the highest in Oregon.
It was named after
a British admiral and first described in 1792 by William Broughton,
member of an expedition under command of
Captain George Vancouver.
The first geologic reconnaissance primarily described the existing
glaciers.
-- From:
Swanson, et.al., 1989, IGC Field Trip T106:
Cenozoic Volcanism in the Cascade Range and Columbia Plateau,
Southern Washington and Northernmost Oregon: American
Geophysical Union Field Trip Guidebook T106.
Felt earthquakes on
Mount Hood
(Oregon) occur every 2 years on the average.
Seismic monitoring,
in effect since 1977, indicates a generalized
concentration of earthquakes just south of the summit area and 2-7 kilometers
below sea level. A seismic swarm in July 1980, during which nearly
60 earthquakes (mostly 5-6 kilometers deep with a
maximum bodywave magnitude of 2.8) recorded in a 5-day period,
prompted development of
an emergency response plan to coordinate local
authorities in the event of future eruption.
-- From:
Swanson, et.al., 1989, IGC Field Trip T106:
Cenozoic Volcanism in the Cascade Range and Columbia Plateau,
Southern Washington and Northernmost Oregon: American
Geophysical Union Field Trip Guidebook T106.
The
Three Sisters area (Oregon)
contains 5 large volcanic cones of Quaternary age--
North Sister, Middle Sister, South Sister,
Broken Top, and
Mount Bachelor.
From:
Hoblitt, et.al., 1987,
Volcanic Hazards with Regard to Siting Nuclear-Power Plants
in the Pacific Northwest: USGS Open-File Report 87-297
North Sister is the oldest of the
Three Sisters
(Oregon), and is
deeply dissected and probably has been inactive
for at least 100,000 years.
Middle Sister is intermediate in age between North and South Sister, and
was active in late Pleistocene but not postglacial time.
South Sister is the least dissected; its basaltic andesite
summit cone has a well preserved crater.
Most of South Sister predates late
Wisconsin glaciation and is therefore older than 25,000 years,
however, eruptions of rhyolite from flank vents have occurred as
recently as 2000 years ago.
-- From:
Scott and Gardner, 1990,
Field trip guide to the central Oregon High Cascades,
Part 1: Mount Bachelor-South Sister area:
Oregon Geology, September 1990, v.42, n.5,
and
Hoblitt, et.al., 1987,
Volcanic Hazards with Regard to Siting Nuclear-Power Plants
in the Pacific Northwest: USGS Open-File Report 87-297.
Crater Lake Caldera, Oregon, with Wizard Island Cinder Cone --
From a probable altitude of roughly 12,000 feet, the top of former
Mount Mazama was lost to eruption and collapse
that left the present huge crater and the deepest lake
(
Crater Lake
- 1,932 feet)
in North America. Explosive eruptions
built
Wizard Island
(at least 800-900 years ago)
and two other cones (submerged) on present crater floor.
From:
Foxworthy and Hill, 1982,
Volcanic Eruptions of 1980 at Mount St. Helens, The First 100 Days:
USGS Professional Paper 1249
Mount Shasta (California)
has erupted, on the average, at least once per 800 years during the
last 10,000 years, and about once per 600 years during the last 4,500 years. The
last known eruption occurred about 200 radiocarbon years ago.
-- From: Miller, 1980, Potential Hazards from Future Eruptions in the
Vicinity of Mount Shasta Volcano, Northern California: USGS Bulletin 1503.
The most recent eruptive activity occurred at
Lassen Peak
(California) in 1914-1917 A.D.
This eruptive episode began on May 30, 1914, when a small
phreatic eruption
occurred at a new vent near the summit of the peak.
More than 150 explosions of various sizes
occurred during the following year.
By mid-May 1915, the eruption changed in character;
lava
appeared in the summit crater and subsequently
flowed about 100 meters over the west and probably over
the east crater walls. Disruption of the sticky lava
on the upper east side of Lassen Peak on May 19 resulted in an
avalanche of hot rock
onto a snowfield. A
lahar
was generated that reached more than 18 kilometers down
Lost Creek. On May 22, an explosive
eruption produced a pyroclastic flow that devastated
an area as far as 6 kilometers northeast of the summit.
The eruption also generated lahars that traveled more
than 20 kilometers down Lost Creek and floods that went down Hat Creek. A
vertical eruption column
resulting from the pyroclastic eruption
rose to an altitude of more than 9 kilometers above the vent
and deposited a lobe of
pumiceous tephra
that can be
traced as far as 30 kilometers to the east-northeast. The fall of fine ash was
reported as far away as Elko Nevada, more than 500 kilometers east of Lassen Peak.
Intermittent eruptions of
variable intensity continued until about the middle of 1917.
-- From:
Hoblitt, et.al., 1987, Volcanic Hazards with Regard to Siting Nuclear-Power
Plants in the Pacific Northwest: USGS Open-File Report 87-297
Dante's Peak is a man-made Cascade volcano created for the
1997 movie Dante's Peak,
starring Pierce Brosnan and
Linda Hamilton. The peak itself was a 100 square foot by 35 foot high wood and
steel structure built on a sound stage in Los Angeles and wheeled
onto a tarmac to be shot against the sky and later composited with live action
footage shot on location (Wallace, Idaho). Computer-generated smoke, ash and
lava were created as special effects. (Info courtesy: Universal Pictures Marketing)
Mount Wilshire is a fictitious volcano which erupted in the La Brea Tar Pits
in Los Angeles, California, in the
1997 movie Volcano, starring Tommy Lee Jones.
The
Alaska Peninsula and the Aleutian Islands
have about 80 major volcanic
centers that consist of one or more volcanoes.
-- From: Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
Alaskan volcanoes
have produced one or two eruptions per year since 1900.
At least 20 catastrophic
caldera-forming
eruptions have occurred in the past 10,000 years; the awesome
eruption of 1912 at Novarupta
in the Katmai National Monument is the most recent.
Scientists are particularly concerned about the volcanoes whose eruptions can
affect the Cook Inlet region, where 60 percent of Alaska's population lives.
-- From: Brantley, 1994, Volcanoes of the United States: USGS General
Interest Publication.
The
Hawaiian Islands
are the tops of gigantic volcanic mountains formed by countless eruptions of
fluid
lava
over several million years; some tower more than 30,000 feet above the
sea floor.
The Islands are composed of linear chains of
shield volcanoes
including
Kilauea and Mauna Loa
on the island of Hawaii --
two of the world's most active volcanoes.
-- From:
Tilling, et.al., 1987, Eruptions of Hawaiian Volcanoes: Past, Present, and
Future: USGS General Interest Publication, and
Tilling, 1985, Volcanoes: USGS General Interest Publication.
The Hawaiian
shield volcanoes
are the largest mountains on Earth. Mauna Kea Volcano rises 13,796 feet above
sea level but extends about 19,700 feet below sea level to meet the deep ocean
floor, its total height is nearly 33,500 feet, considerably higher than the
height of the tallest mountain on land, Mount Everest (Chomolungma) in the
Himalayas (29,028 feet above sea level). Mauna Loa stands not quite as high as
Mauna Kea but is much larger in volume.
-- From:
Tilling, et.al., 1987, Eruptions of Hawaiian Volcanoes: Past, Present, and
Future: USGS General Interest Publication.
Some of the Earth's grandest mountains are
composite volcanoes --
sometimes called stratovolcanoes. They are typically steep-sided,
symmetrical cones of large dimension built of alternating layers of
lava flows,
volcanic ash,
cinders, blocks, and bombs
and may rise as much as 8,000 feet above their bases. Some of the most
conspicuous and beautiful mountains in the world are composite volcanoes,
including
Mount Fuji in Japan,
Mount Cotopaxi in Ecuador,
Mount Shasta in California,
Mount Hood in Oregon,
Mount St. Helens and
Mount Rainier in Washington.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication.
Shield volcanoes
are built almost entirely of fluid
lava flows.
Flow after flow pours out in all directions from a central summit vent, or group
of vents, building a broad, gently sloping cone of flat, domical shape, with a
profile much like that a warrior's shield.
In northern
California and
Oregon,
many shield volcanoes have
diameters of 3 or 4 miles and heights of 1,500 to 2,000 feet.
The
Hawaiian Islands
are composed of linear
chains of these volcanoes including
Kilauea and Mauna Loa on the
island of Hawaii -- two of the world's most active volcanoes.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication.
The largest and most explosive volcanic eruptions eject tens to hundreds of
cubic kilometers of
magma
onto the Earth's surface. When such a large volume of
magma is removed from beneath a volcano, the ground subsides or collapses into
the emptied space, to form a huge depression called a
caldera.
Some
calderas are more than 25 kilometers in diameter and several kilometers deep.
The caldera now filled by Oregon's
Crater Lake
was produced by an eruption that destroyed a volcano the size of
Mount St. Helens and sent
volcanic ash
as far east as Nebraska.
-- From:
Brantley, 1994, Volcanoes of the United States:
USGS General Interest Publication and
Wright and Pierson, 1992, Living With Volcanoes, The
U.S. Geological Survey's Volcano Hazards Program: USGS Circular 1973.
An
earthquake
is the shaking of the ground caused by an abrupt shift of
rock along a fracture in the Earth, called a fault. Within seconds, an
earthquake releases stress that has slowly accumulated within the rock,
sometimes over hundreds of years. ...
Earth scientists believe that most earthquakes
are caused by slow movements
inside the Earth that push against the Earth's brittle, relatively thin
outer layer,
causing the rocks to break suddenly.
-- From:
Noson, Qamar, and Thorsen, 1988,
Washington State Earthquake Hazards:
Washing State Department of Natural Resources,
Washington Division of Geology and Earth Resources Information Circular 85
On
May 18, 1980,
at
Mount St. Helens,
data shows that an estimated 7-20 seconds
elapsed between the triggering earthquake and the onset of the flank
collapse. During the next 15 seconds, first one large block slid away, then
another large block began to move, only to be followed by still another block.
The series of slide blocks merged downslope into a gigantic
debris avalanche,
which moved northward at speeds
of 110 to 155 miles per hour.
Covering an area of about 24 square miles, the debris avalanche advanced more
than 13 miles down the North Fork of the Toutle River and filled the valley to
an average depth of about 150 feet; the total volume of the deposit was about
0.7 cubic mile.
-- From:
Tilling et.al., 1990, The Eruptions of Mount St. Helens: Past, Present, and
Future: USGS General Interest Publication.
The term "pyroclastic" -- derived from the Greek works pyro (fire) and
klastos (broken) -- describes materials formed by the fragmentation of
magma and rock by explosive volcanic activity.
Pyroclastic flows
-- sometimes called nuees ardents (French for
"glowing clouds') -- are hot, often incandescent mixtures of volcanic fragments
and gases that sweep along close to the ground. Depending on the volume of
material, proportion of solids to gas, temperature, and slope gradient, the
flows can travel at velocities as great as 450 miles an hour.
Most
volcanic ash
is basically fine-grained pyroclastic material composed of tiny particles of
explosively disintegrated old volcanic rock or new magma.
Larger sized pyroclastic fragments are called
lapilli, blocks, or bombs.
-- From:
Tilling et.al., 1990, The Eruptions of Mount St. Helens: Past, Present, and
Future: USGS General Interest Publication.
Pyroclastic flows
can be extremely destructive and deadly because of their high temperature and
mobility. During the
1902 eruption of Mont Pelee (Martinique, West Indies),
for example, a nuee ardente demolished the coastal city of St. Pierre, killing
nearly 30,000 inhabitants.
-- From:
Tilling et.al., 1990, The Eruptions of Mount St. Helens: Past, Present, and
Future: USGS General Interest Publication.
Scientists use the term
magma
for molten rock underground and
lava
for molten rock (and contained gases) that
breaks through the Earth's surface.
Originating many tens of miles beneath the ground, magma commonly
contains some crystals, fragments of surrounding (unmelted) rocks, and dissolved
gases, but it is primarily a liquid composed principally of oxygen, silicon,
aluminum, iron, magnesium, calcium, sodium, potassium, titanium, and manganese.
Lava is red hot when it pours or blasts out of a vent but soon changes to dark
red, gray, black, or some other color as it cools and solidifies. Very hot,
gas-rich lava containing abundant iron and magnesium is fluid and flows like hot
tar, whereas cooler, gas-poor lava high in silicon, sodium, and potassium flows
sluggishly, like thick honey in some cases or in others like pasty, blocky
masses.
-- From:
Tilling, Heliker, and Wright, 1987, Eruptions of Hawaiian Volcanoes:
Past, Present, and Future: USGS General Interest Publication
and
Tilling, 1985, Volcanoes:
USGS General Interest Publication.
The violent separation of gas from
lava
may produce rock froth called
pumice.
Some of this froth is so light -- because of the many gas
bubbles -- that it floats on water.
-- From:
Tilling, 1985, Volcanoes: USGS General Interest Publication.
Volcanic domes
are masses of solid rock that are formed when viscous lava
is erupted slowly from a vent. If the lava is viscous enough, it will pile up
above the vent to form a dome rather than move away as a
lava flow.
The sides of most domes are very steep and typically are mantled with unstable
rock debris formed during or shortly after dome emplacement. Most domes are
composed of silica-rich lavas that have a lower gas content than do the lavas
erupted earlier in the same eruptive sequence; nevertheless, some dome lavas
still contain enough gas to cause explosions within a dome as it is being formed.
From:
Miller, 1989, Potential Hazards from Future Volcanic Eruptions in California:
USGS Bulletin 1847.
During many volcanic eruptions, fragments of
lava
or rock are blasted into the
air by explosions or carried upward by a
convecting column of hot gases.
These fragments fall back to earth on and downwind from their source vent to form a
pyroclastic-fall or
"ash" deposit.
Pyroclastic-fall deposits, referred to as tephra,
consist of combinations of pumice, scoria, dense-rock material,
and crystals, that range in size from ash (<2mm) through
lapilli (2-64mm) to blocks (>64mm).
Eruptions that produce tephra range from short-lived weak ones that
eject debris only a few meters into
the air, to cataclysmic explosions that throw debris to heights of several tens
of kilometers.
-- From:
Miller, 1989,
Potential Hazards from Future Volcanic Eruptions in California:
U.S. Geological Survey Bulletin 1847
Lahar is an Indonesian word describing
mudflows and debris flows
that originate from the slopes of a volcano.
Both types of flows contain a high concentration of rock debris to give
them the internal strength necessary to transport huge boulders as well as
buildings and bridges and to exert extremely high impact forces against objects
in their paths. Debris flows are coarser and less cohesive than
mudflows. As lahars become dilute in downstream direction they become
hyperconcentrated streamflows. Lacking internal strength, the mixture of
rock debris and water takes on different flow properties. The coarser debris in
this type of flow is no longer held in suspension by matrix strength and
therefore settles to the bottom of the flow.
-- From:
Brantley and Power, 1985,
Reports from the U.S. Geological Survey's Cascades Volcano Observatory at
Vancouver, Washington:
Earthquake Information Bulletin, v.17, n.1, January-February 1985.
Lahars
can be of any size. They may be as small as several centimeters
wide and deep, flowing less than one meter per second. Steep, unvegetated
slopes during a heavy rain are often good sites to observe such small flows. At
the other extreme, they can be a few hundred meters wide, tens of meters deep,
flow at several tens of meters per second, and travel over 100 kilometers from a
volcano. Such catastrophic lahars are triggered by volcanic eruptions or by
massive landslides such as the one that occurred on
May 18, 1980, at
Mount St. Helens volcano.
-- From:
Brantley and Power, 1985,
Reports from the U.S. Geological Survey's Cascades Volcano Observatory at
Vancouver, Washington:
Earthquake Information Bulletin, v.17, n.1, January-February 1985.
Lahars
are commonly initiated by:
1) large landslides of water-saturated debris,
2) heavy rainfall eroding volcanic deposits,
3) sudden melting of snow and ice near a volcanic vent by radiant heat or
on the flanks of a volcano by
pyroclastic flows,
or
4) breakout of water from glaciers, crater lakes, or from
lakes dammed by volcanic eruptions.
Since 1980, lahars have formed by all of these processes at
Mount St. Helens.
-- From:
Brantley and Power, 1985,
Reports from the U.S. Geological Survey's Cascades Volcano Observatory at
Vancouver, Washington:
Earthquake Information Bulletin, v.17, n.1, January-February 1985.
URL for CVO HomePage is:
<http://vulcan.wr.usgs.gov/home.html>
URL for this page is:
<http://vulcan.wr.usgs.gov/LivingWith/VolcanicFacts/misc_volcanic_facts.html>
If you have questions or comments please contact:
<GS-CVO-WEB@usgs.gov>
06/11/08, Lyn Topinka
