Geog Practice Question 3

Impact of Volcanic Hazards in Developed Countries

The May 18th, 1980 eruption of Mount St. Helens in the United States is an example of a Plinian eruption. Describe the volcanic hazards and their effects that resulted from this eruption. (9)

• Plinian eruption
  -Characterised by large eruptive columns that are powered upward partly by the thrust of expanding gases, and by convective forces with exit velocities of several hundred meters per second.
  - Large amount of ash and pumice and produced during the eruption.
  - The eruption may be accompanied by pyroclastic flows.
  - The ejection of large volumes of ash and magma may result in a caldera collapse.
  - Many stratovolcano tend to erupt in this manner.
  
  
• Volcanic Hazards and Effects
  - Ash Fall
  - After the explosive lateral blast of the volcano, a strong and vertically directed explosion of ash and steam occurred, giving rise to a column of ash that was almost 20 kilometres high.
  - By the time the eruption stopped, the ash cloud had already spread to the central United States.
  -The ash particles in the atmosphere gave rise to lightning, causing many forest fires as a result.
  - During ash falls, visibility was reduced and roads had to be closed to traffics for up to weeks.
  - Air transportation was disrupted as several airports in eastern Washington shut down due to ash accumulation and poor visibility. Over a thousand commercial flights were also cancelled as a result.
  - The ash infiltrated many spaces and was highly abrasive, leading to the contamination of oil systems, the clogging of air filters and the abrasion of moving surfaces. Thus, many machinery were damaged as a result.
  - In areas where there was high ash accumulation, many crops were killed. On the other hand, crops survived in fields where ash accumulation was much lower. Output of these agricultural fields even increased as a result of higher summer precipitation brought on by the ash falls.
  - The ash falls added on to the economic cost of the volcanic eruption. US$2.2 million were spent to remove the ash and the entire process took up to 10 weeks in some areas.
  
  
• Pyroclastic flows
  - A few hours after the start of the lateral blast, pyroclastic flows began to form and continued to occur during the 5 hours of intense eruptive activity. At least 17 pyroclastic flows were observed during the eruption.
  - These flows were deadly since the full volume and force of pyroclastic materials were directed sideways by the lateral eruption of Mount St. Helens. This resulted in flows with high velocities and high temperatures with the ability to destroy everything in their paths.
  - Steam-blast explosions were observed when the hot pyroclastic flows entered water bodies like the Spirit Lake. The explosions formed many pits on the sides of the pyroclastic flow deposits. Plumes of ash and steam as high as 1.9 kilometres were observed as well.
  - When the pyroclastic flows encountered the North Fork of the Toutle River, the debris were deposited in the river. The accumulation and eventual overflow of the debris collected in the river was to lead to the formation of destructive lahars.
  
  
• Lahars
  - In the North Fork of the Toutle River, the water-saturated parts of the massive debris avalanche deposits began to collect and eventually overflow, giving rise to the largest and most destructive lahar.
  - 0.01 cubic kilometres of water, mud and debris were deposited into the Swift Reservoir when lahars moved along the south-eastern flank of the volcano and along the drainages of the Swift Creek, Pine Creek, and Muddy River.
  - The impact of the lahars’ flow front are so strong that lahars can even crush or carry away buildings. The forest around Mount St. Helens were destroyed. More than 200 homes and over 300 kilometres of road were destroyed by these lahars, rendering many people homeless.
  - Valuable land were buried by the layers of rock and mud from the lahars, lowering their value and rendering them useless for agriculture. This added on to the economic cost of the volcanic eruptions.
  
  
• Combined effects of the volcanic hazards
  - The devastation on the people and their property were widespread. The death toll was 57 and many others were injured during the eruption.
  - The fauna of the forest around Mount St. Helens was affected as well. An estimated number of 7000 big animals like bears and deer died during the eruption along with birds and most small mammals.
  - Immediately after the eruption, tourism, an important industry in Washington, was badly affected. Conventions, meetings, and social gatherings also were canceled or postponed at cities and resorts elsewhere in Washington.
  - Official figures estimate the cost of the destruction wrecked by the eruption to be US$1.1 billion. The actual cost remain difficult to determine.
  - A few months after the eruption, there were reports of residents, who had coped successfully during the eruption, suffering from stress and emotional problems. Funding for mental health programs for these residents were requested.
  - The May 18th eruption also resulted in the collapse of the summit of Mount St. Helens, forming a caldera instead.

Geog Practice Question 2

Impact of Volcanic Hazards in Less Developed Countries

2) Mt Merapi, a volcano in central Java, Indonesia is the most active volcano in the country. Its eruptions have caused high death tolls, fatalities as well as destruction. Despite this, thousands of people live on the flanks of Mt Merapi.

Discuss about the dangers Mt Merapi’s eruptions impose and explain why people still live near volcanoes despite these dangers, with context to Mt Merapi.

_______________________________________________________


Essay outline

Intro:
Mt Merapi is a stratovolcano, composed of viscous andesitic lava. She is one of the volcanoes located within the Pacific Ring of Fire. Eruptions are typically effusive. Hazards faced at Mt Merapi are mainly, pyroclastic flows, lahars as well as landslides.

Hazard 1: Pyroclastic flows (refer to volcanic hazards Part 1: LDCs)

Hazard 2: Lahars (refer to volcanic hazards Part 2: LDCs)

Hazard 3: Landslides (refer to volcanic hazards Part 2: LDCs)


Link to next segment of question:
As seen from above, Mt Merapi poses a high level of danger to the people living on and near her flanks. However, many are unwilling to leave for safer grounds. Volcanoes have a wide range of effects on humans, negatively and positively. People live near Mt Merapi to reap the benefits that she provides.

Benefit 1: Tourism
People flock from all over the world to visit volcanoes. Mt Merapi is no exception. Being an LDC, Indonesia reaps a good amount of profit from Merapi-seeking tourists. A number of jobs are created for this industry. This includes work in hotels, food and beverage and gift shops. Locals are also often hired as tour guides.

Benefit 2: Agriculture
Being a LDC, agriculture is an important source of income for many Indonesians. The rich soil that Mt Merapi provides allows for healthy crops to be grown on its land. The ash formed from eruptions mixes with the soil on the land, making it very rich in minerals. Healthy crops cultivated and rich harvests are the main reason why many people are induced into living on the flanks of Mt Merapi. Besides, the people have become adept in the skills of harvest at volcanic flanks it will be difficult for them to move and change their type of occupation.

Benefit 3: Products
- Pumice: widely used for grinding and polishing metals, stones, and other materials.
- Metals: gold, silver, mercury, copper, zinc, lead
- Gemstones: opal
- Building materials: cinder tracks for athletics, naturally broken aggregates


Conclusion:
All in all, it can be seen that there is a substantial number of reasons why people wish to live near Mt Merapi despite it being an active volcano. Practicality thus attracts people to live near Mt Merapi. Other than the reasons stated above, other personal reasons like the people living there all their lives and religious beliefs as well as for the fact that there are many active volcanoes on the island of Java and should they move, would still be near an active volcano. Therefore even with the dangers posed; people are still willing to risk their lives for the reasons discussed above.

Geog Practice Question 1

Formation of Volcano

1) Cascade Range of USA, in which a linear belt of volcanoes can be found, is formed through the convergence of Juan de Fuca plate and North American plate, as shown in Figure 1. Explain how the convergence of the two plates leads to the formation of the volcanoes.

Figure 1
Source:http://vulcan.wr.usgs.gov/Imgs/Gif/PlateTectonics/Maps/map_plate_tectonics_cascades.gif

Answer:

• Juan De Fuca Plate is an oceanic plate, while North American Plate is a continental plate. Oceanic plate is denser than continental plate. Therefore, when Juan De Fuca plate converges with North American plate, it subducts underneath the less dense North American plate.
  
  
• As Juan De Fuca plate subducts, it is subjected to progressively higher temperatures and pressure. Water trapped in the sediments is probably squeezed out into the mantle wedge overlying the descending plate. Water has the effect of lowering the melting temperature of the mantle, thus causing it to melt. As the hybrid magma, derived partially from the overlying mantle rises, it reacts extensively with the overlying crust to produce a magma that is even more complex. This magma may contain components derived from oceanic sediments, from metamorphosed oceanic basalt, from the peridotite in the mantle wedge and from the overlying crust. On the way to the surface, the magma also may mix with other batches of magma.
  
  
• Having lower density than the surrounding, the magma buoyantly rises through the overlying mantle to form a linear belt of volcanoes parallel to the oceanic trench between the Juan de Fuca plate and North American plate. This is how the linear belt of volcanoes in the Cascade Range may be formed.
  
  
• This diagram can be drawn in the answer. (Other diagrams with the same idea are also accepted)
  
  

Source:
http://vulcan.wr.usgs.gov/Imgs/Gif/PlateTectonics/Maps/map_plate_tectonics_cascades.gif

Impact of Volcanic Hazards in Less Developed Countries

To discuss the effects of primary and secondary volcanic hazards on people and property in Less Developed Countries, we will use the case study of Mount Merapi.


Effects of Volcanic Hazards in Less Developed Countries
Example: Mount Merapi

Mount Merapi
Source: http://volcano.und.edu/vwdocs/volc_images/southeast_asia/indonesia/Merapi1.jpg

Merapi, which is a stratovolcano, is Indonesia’s most active volcano and well known for partial collapse of lava domes and the generation of pyroclastic flows. The name M erapi means ‘Mountain of Fire’. It is tall (2.8 km or 1.7 miles high) and has steep slopes. The top of the volcano sometimes has a normal crater, but usually a lava dome fills the crater. The dome plugs up the volcano, making it difficult for other lava and ash to escape. A broad gouge funnels lava and ash flows from the top of Merapi to the south slopes of the volcano. The top of the mountain has no vegetation because erupted ash often falls there. Dense vegetation covers the flanks of the volcano. Many farmers live in villages around the volcano. The volcanic ash makes rich soil for growing crops, but it is a dangerous place to live. Yogyakarta city, with a population of 3 million, is 15 miles (25 km) south of Merapi. About 50,000 people live on the southwest flank of the volcano.

Lava dome at the summit of Merapi. During 1982, the lava dome was growing about 80,000-100,000 cubic meters per month. The dome collapsed in late November, creating nuee ardentes.
Source: http://volcano.und.edu/vwdocs/volc_images/southeast_asia/indonesia/Merapi2.jpg

Like all volcanoes, Merapi has eruptions of different sizes. The volcano has had numerous moderate to large (1 million cubic m) eruptions. Small eruptions happen every 2-3 years, bigger ones every 10-15 years, and very large ones every 50-60 years. The biggest eruptions occurred in the years 1006, 1786, 1822, 1872 and 1930. The eruption of 1006 spread ash all over the central part of the island of Java. The destruction was so bad that the existing Hindu kingdom was destroyed and the island was taken over by Muslims.

Eruptions mainly begin with pyroclastic flows followed by widespread pyroclastic air fall. Plinian to subplinian eruptions are common. These older deposits indicate that Merapi is capable of eruption styles very different from those currently observed.

Pyroclastic flow deposit on Merapi.
Source: http://volcano.und.edu/vwdocs/volc_images/southeast_asia/indonesia/Merapi3.jpg

A history of violent eruptions led to Mount Merapi being designated as one of the "Decade Volcanoes." These volcanoes have been identified by the International Association of Volcanology and Chemistry of the Earth's Interior as requiring special study because of the danger they pose to populated regions. Mount Merapi's last large ash eruption occurred in 1984. A particularly devastating eruption took place in 1930, when 1,300 were killed by an eruption here. Another eruption, in 1976, killed 28 people and destroyed homes of 1,176 people. Since 1984, Mount Merapi had erupted repeatedly as glowing avalanches flowed from a growing lava dome. These glowing avalanches, or nuee ardentes, moved down a different river drainage towards the west.

Eruption on 22 November 1984

Mount Merapi erupted on November 22 at about 10:15 a.m. local time. Inconsistent news reports on the number of casualties suggest that at least 34 people were killed, several hundred were injured, and hundreds of homes were destroyed. The eruption began with steam explosions and ejection of rocks and gravel over the surface of the cone. The steam plume reached about 800 meters high. After 25 minutes of such activity, the main eruption began and sent an ash column roughly 10 kilometers high. An advisory was issued to warn aircraft from entering the ash plume and being subject to engine damage and endangering the lives of those onboard. Ash fallout was heavy as far as 45 kilometers to the northwest of Mount Merapi. On the ground, a pyroclastic flow of hot ash, gas, and other suspended particles swept 6 kilometers to the southwest down the Boyong River drainage and through Turgo Village in the Yogyakarta District. Many of the injured suffered severe burns from the hot gases. Most of the casualties appear to be in two small villages. Over 6,000 people were evacuated from the area.

Impact of Volcanic Hazards in Developed Countries

To discuss the effects of primary and secondary volcanic hazards on people and property in Developed Countries, we will use the case study of Mount St. Helens.

Effects of Volcanic Hazards in Developed Countries
Example: Mount St. Helens

Mount St. Helens is a stratovolcano in Washington, the United States of America. The volcano is most famous for its eruption on 18 May 1980, which is the worst volcanic disaster and one of the most significant geologic events in the United States during the 20^th century. The actual cost of the destruction wrecked by the eruption remain difficult to determine even though official figures estimate the cost to be US$1.1 billion.

Mount St. Helens on May 17, 1980, one day before the devastating eruption.
Source: http://vulcan.wr.usgs.gov/Imgs/Jpg/MSH/Images/MSH80_st_helens_from_johnston_ridge_05-17-80_med.jpg

Before 1980, Mount St. Helens, known for its serenity and symmetry, was known as the “Fujiyama of America”. The majority of 20^th century residents and visitors did not think of Mount St. Helens as a volcanic hazard but as a peaceful mountain for leisure activities.

However, as early as 16 March 1980, the first signs of volcanic activity in the form of earthquakes were observed. It was only on March 27 when the volcano began to emit ash and steam. There was visible deformation and swelling of the volcano due to the movement of magma from the magma chamber into the volcano. The north face of Mount St. Helens was especially affected by the deformation and the area became known as the “bulge”.

A "bulge" developed on the north side of Mount St. Helens as magma pushed up within the peak.
Source: http://vulcan.wr.usgs.gov/Imgs/Jpg/MSH/Images/MSH80_bulge_on_north_side_04-27-80_med.jpg

As seen from the above photograph, the visible “bulge” developed on the north side of the volcano. From angle and slope-distance measurements, it was observed that the “bulge” was growing at a rate of nearly 1.5 metres per day.

On May 18, the deformed and unstable north flank of the volcano suddenly collapsed, apparently due to an earthquake of magnitude 5.1 beneath the volcano. This collapse of the north flank gave rise to a landslide-debris avalanche, which moved northwards at speeds of 175 to nearly 250 km per hour, recorded.

The sudden removal of the “bulge” on the north face of the volcano abruptly released the pent-up pressure of the volcanic system of Mount St. Helens and triggered an almost immediate and explosive lateral blast. The blast’s quickly increased from its initial velocity of about 354 kilometres per hour to about 1078 kilometres per hour. The lateral blast, loaded with volcanic debris, caused widespread destruction as far as 30 kilometres from the volcano.

Ash fall and its effects

A strong, vertically directed explosion of ash and steam began very shortly after the lateral blast. The resulting column of ash rose very quickly into the atmosphere, attaining a height of almost 20 kilometres.

Near the volcano, the ash particles in the atmosphere gave rise to lightning which started many forest fires in return. More ash was emitted into the atmosphere as the eruption continued for 9 hours, adding to the growth of the ash cloud. By the time the eruption subsided and stopped on May 19, the ash cloud had spread to the central United States.

Some of the ash also drifted around the globe, only reaching the Earth’s surface after several weeks. However, the smallest fragments and aerosols remained suspended in the atmosphere for years which eventually had an impact on modifying the global climate. The aerosols participate in complex chemical reactions in the stratosphere, altering chlorine and nitrogen chemical compounds. This effect led to the formation of radicals and, accompanied by chlorofluorocarbon (CFC) pollution, contributed to the depletion of the ozone layers as the radicals break down ozone molecules that protect us from ultraviolet rays from the sun.

Pyroclastic flows and its effects

Pyroclastic flows were observed a few hours after the start of the lateral blast and continued to occur intermittently during the next 5 hours of strong eruptive activity. At least 17 separate pyroclastic flows occurred during the May 18 eruption, and their aggregate volume was about 0.21 cubic kilometres.

When the hot pyroclastic flows encountered water bodies such as Spirit Lake, it led to steam-blast explosions as water flashed explosively into steam. Plumes of ash and steam were sent as high as 1.9 kilometres above the ground. These steam-blast eruptions formed many explosion pits on the sides of the pyroclastic flow deposits, at the south shore of Spirit Lake, and along the upper part of the North Fork of the Toutle River.

Pyroclastic flows were very dangerous as they were directed sideways by the lateral eruption of Mount St. Helens. The force and full volume of the pyroclastic materials are forced down the volcano and the resulting high velocities and temperatures of the flow can destroy everything in their paths.

Lahars and their effects

The largest and most destructive lahar developed several hours later in the North Fork of the Toutle River, when the water-saturated parts of the massive debris avalanche deposits began to collect and eventually overflow. The resulting lahar in the Toutle River drainage area dumped more than 0.05 cubic kilometres of sediment along the lower Cowlitz and Columbia Rivers.

Lahars occurred along the southeast flank of the volcano-along the Swift Creek, Pine Creek, and Muddy River drainages and emptied nearly 0.01 cubic kilometres of water, mud, and debris into the Swift Reservoir. Fortunately, the volume of the additional load was insufficient to cause overtopping even if the reservoir had been full, thus preventing further damage to property and loss of lives.

Lahars can case high economic and environmental damage and in the case of the May 18 eruption of Mount St. Helens, it destroyed the forests around the volcano. The impact of a lahar’s flow front can remove and destroy anything in its path, in fact lahars can even crush or carry away buildings. Valuable land may be buried by layers of rock debris, lowering their value and rendering them unusable for agriculture, adding on to the economic cost of lahars. These flows can destroy bridges and roads, trapping people in areas that may be vulnerable to other volcanic hazards.

Aftermath of the May 18 Eruption

The May 18, 1980, eruption was the most destructive in the history of the United States. Landscape changes caused by the eruption was obvious especially from high-altitude photographs and the devastation on people and their property widespread, claiming 57 lives and injuring many others.

More than 200 homes and over 185 miles (300 kilometers) of roads were destroyed by the 1980 lahars.

Source: http://vulcan.wr.usgs.gov/Imgs/Jpg/MSH/Images/MSH81_damaged_home_south_fork_toutle_river_07-19-81_med.jpg

More than 200 homes and over 300 kilometres of roads were destroyed by the 1980 lahars. Pictured here is a damaged home along the South Fork Toutle River. The lateral blast, debris avalanche, mudflows, and flooding caused extensive damage to land and man-made structures, rendering many people homeless.

There was also a large impact on the fauna in the Mount St. Helens area. It is estimated that nearly 7,000 large animals like bears and deer perished in the area most affected by the eruption, as well as all birds and most small mammals. Many small animals, mainly burrowing rodents, frogs, salamanders, and crawfish, managed to survive because they were below ground level or water surface when the disaster struck.

In areas of thick ash accumulation, many agricultural crops, such as wheat, apples, potatoes, and alfalfa, were destroyed. As for areas blanketed only by a thin layer of ash, many crops survived. In fact, the apple and wheat production in 1980 was higher than normal due to greater-than-average summer precipitation as a result of the ash falls. Effects of the ash fall on the water quality of streams, lakes, and rivers were short lived and minor.

May 18, 1980- ash along the roadside, Connell, Washington.
Source: http://vulcan.wr.usgs.gov/Imgs/Jpg/MSH/Images/MSH80_may18_ash_road_connell_washington_06-80_med.jpg

The photograph shows ash along the roadside in Connell, Washington. Visibility was reduced during the ash falls, forcing roads to close to traffic for up to weeks. Air transportation was disrupted as several airports in eastern Washington shut down due to ash accumulation and poor visibility. Over a thousand commercial flights were also cancelled as a result.

The volcanic ash caused problems for internal-combustion engines and other mechanical and electrical equipment. The ash was able to infiltrate most openings and was highly abrasive, thus contaminating oil systems, clogging air filters, and scratching moving surfaces. In fact, there were cases where blackouts were caused by the coating of fine ash on electric transformers, causing short circuit. The sewage-disposal systems of several areas were plagued by ash clogging and damage to pumps, filters, and other equipment.

The removal and disposal of the ash was not easy. Ash removal cost $2.2 million and took 10 weeks in Yakima. To minimize the effect of wind on ash dumps, the surfaces of some disposal sites have been covered with topsoil and seeded with grass. About 191 138 square meters of ash have been stockpiled at five sites for constructional and other beneficial economic uses in the future.

The eruption had indirect costs in the form of its effects on residents in the affected areas. Unemployment in the immediate region of Mount St. Helens rose quickly in the weeks following the eruption before returned to normal once the operations to clean up the ash and to salvage timber began. Several months after May 18, a few residents reported suffering stress and emotional problems, even though they had coped successfully during the crisis. Funding for mental health programs were requested to help these people.

Immediately after the eruption, tourism, an important industry in Washington, was badly affected. Conventions, meetings, and social gatherings also were canceled or postponed at cities and resorts elsewhere in Washington. The negative impact on Washington’s tourism proved only to be temporary as the tourists began to return to Mount St. Helens, possibly attracted by its reawakening.

Mount St. Helens is considered to be one of the most beautiful and interesting of the Cascade volcanic peaks.
Source: http://vulcan.wr.usgs.gov/Imgs/Jpg/MSH/Images/MSH82_st_helens_spirit_lake_reflection_05-19-82_med.jpg

Mount St. Helens is no longer symmetrical and has an amphitheatre-shaped caldera instead. It is still considered to be one of the most beautiful and interesting of the Cascade volcanic peaks. Mount St. Helens and the devastated area is now within the 110,000-acre Mount St. Helens National Volcanic Monument, under jurisdiction of the United States Forest Service. Visitor centers, interpretive areas, and trails are being established as thousands of tourists, students, and scientists visit the monument daily.

Volcanic Hazards (Part 2)

Volcanic Landslides

Landslides are large masses of rock and soil that fall, slide, or flow very rapidly under the force of gravity. These mixtures of debris move in a wet or dry state, or both. Volcano landslides range in size from small movements of loose debris on the surface of a volcano to massive collapses of the entire summit or sides of a volcano. If the moving rock debris is large enough and contains a large content of water and fine material, the landslide may transform into a lahar and flow down valley more than 100 km from a volcano. Large-scale landslides along coasts or in oceans can also cause tsunamis; the deadliest on record was caused by a landslide in the Unzen volcano in 1792 which killed 16,000 Japanese, due to landslide debris and the resulting tsunami wave.

Landslides are common on volcanoes because their massive cones (1) typically rise hundreds to thousands of meters above the surrounding terrain; and (2) are often weakened by the very process that created them--the rise and eruption of molten rock. Each time magma moves toward the surface, overlying rocks are shouldered aside as the molten rock makes room for itself, often creating internal shear zones or oversteepening one or more sides of the cone. Magma that remains within the cone releases volcanic gases that partially dissolve in groundwater, resulting in a hot acidic hydrothermal system that weakens rock by altering rock minerals to clay. Furthermore, the tremendous mass of thousands of layers lava and loose fragmented rock debris can lead to internal faults and fault zones that move frequently as the cone "settles" under the downward pull of gravity.

A scientist stands on one of the many small hills that form the chaotic surface of a massive landslide deposit in the upper North Fork Toutle River valley below Mount St. Helens volcano (10 km in distance). Before the landslide and eruption on May 18, 1980, a forest grew on this part of the valley floor, and a highway followed the meandering river to Spirit Lake, a popular recreation area.

Source: http://volcanoes.usgs.gov/Imgs/Jpg/MSH/30212265-050_large.jpg

Lahars

Lahar produced as a result of an eruption by Mt. St Helens
Source: http://www.geology.sdsu.edu/how_volcanoes_work/Images/lahars/laharmsh_l.jpg

Lahar is an Indonesian term that describe mudflow or debris flow composed mostly of volcanic materials on the flanks of a volcano. As a lahar rushes downstream from a volcano, its size, speed, and the amount of water and rock debris it carries constantly change. The beginning surge of water and rock debris often erodes rocks and vegetation from the side of a volcano and along the river valley it enters. But as lahars move farther away from a volcano, they will eventually begin to lose its heavy load of sediment and decrease in size.The speed of lahars can ranges 20 to 40 miles per hour and they can travel for more than 50 miles.

Some lahars contain so much rock debris (60 to 90% by weight) that they look like fast-moving rivers of wet concrete. Close to their source, these flows are powerful enough to rip up and carry trees, houses, and huge boulders miles downstream. Farther downstream they entomb everything in their path in mud.

Eruptions may trigger one or more lahars directly by quickly melting snow and ice on a volcano or ejecting water from a crater lake. More often, lahars are formed by intense rainfall during or after an eruption--rainwater can easily erode loose volcanic rock and soil on hillsides and in river valleys

Lahars almost always occur on or near stratovolcanoes because these volcanoes tend to erupt explosively and their tall, steep cones are either snow covered, topped with a crater lake, constructed of weakly consolidated rock debris that is easily eroded, or internally weakened by hot hydrothermal fluids.

Tsunami

Tsunamis are giant sea waves that form when volcanoes erupt in or near large bodies of water, and are a secondary hazard of eruptions, especially very violent caldera-forming events. Volcanic tsunami can be generate in a number of ways, including the eruption of a submarine volcano, the inward collapse of a volcano during or after an eruption, the flow of volcanic debris down the side of a volcano into the sea, large earthquakes associated with the volcano, or by boiling or expelling water out of a hot, collapsed crater.

Volcanic Tremors and Earthquakes

Seismicity is another common accompaniment of volcanic activity. Eruptions are commonly preceded by local earthquakes, which may be caused by the cracking and splitting open of fissures as the magmas chamber inflates. There are three general categories of earthquakes that can occur at a volcano: volcano-tectonic earthquakes, long period earthquakes and volcanic or harmonic tremors.

Volcano-tectonic earthquakes are earthquakes produced by stress changes in solid rock due to the injection or withdrawal of magma (molten rock). These earthquakes can cause land to subside and can produce large ground cracks. These earthquakes can occur as rock is moving to fill in spaces where magma is no longer present.

Long period earthquakes are produced by the injection of magma into the surrounding rock. These earthquakes are a result of pressure changes during the unsteady transport of the magma. When magma injection is sustained, a lot of earthquakes are produced. This kind of earthquakes can be used to predict future occurrences of volcanic eruptions.

Harmonic tremors largely consist of a more or less continuous, low frequency, rhythmic ground motion. It may be associated with actual movement of magma.


Next: Impact of Volcanic Hazards on DCs and LDCs.

Volcanic Hazards (Part 1)

Introduction

Volcanoes produce a wide variety of hazards that can prove fatal and harmful to people as well as destroy property. Large explosive eruptions can endanger people’s lives and obliterate property hundreds of miles away and even affect global climate.

Various Volcanic Hazards
Source: http://pubs.usgs.gov/fs/fs002-97/

Classification of Volcanic Hazards

• Primary volcanic hazard: occurred as a result of volcanic activity itself.
• Secondary volcanic hazard: caused by a primary effect.
  

List of Volcanic Hazards

• Volcanic gases (primary effect)
• Lava flows and domes (primary effect)
• Pyroclastic flows (primary effect)
• Volcanic landslides (secondary effect)
• Lahars (secondary effect)
• Earthquakes (secondary effect)
• Tsunamis (secondary effect)
  

Some of the deadliest volcanic eruptions in the world

Volcanic Gases

Volcanoes emit gases during eruptions. Even when a volcano is not erupting, cracks in the ground allow gases to reach the surface through small openings called fumaroles. he gaseous portion of magma varies from ~1 to 5% of the total weight. More than 90% of all gas emitted by volcanoes is water vapor (steam), most of which is heated ground water (underground water from rain fall and streams). Other common volcanic gases are carbon dioxide, sulphur dioxide, hydrogen sulfide, hydrogen, and fluorine. Sulphur dioxide gas can react with water droplets in the atmosphere to create acid rain, which causes corrosion and harms vegetation. Carbon dioxide is heavier than air and can be trapped in low areas in concentrations that are deadly to people and animals. Fluorine, which in high concentrations is toxic, can be absorbed onto volcanic ash particles that later fall to the ground. The fluorine on the particles can poison livestock grazing on ash-coated grass and also contaminate domestic water supplies.


Lava Flows and Domes

Lava flow moves through an intersection on the south flank of Kilauea
Source: http://volcanoes.usgs.gov/Hazards/What/Lava/lavaflow.html

Lava flows are streams of molten rock that pour or ooze from an erupting vent. Lava is erupted during either nonexplosive activity or explosive lava fountains. Lava flows destroy everything in their path, but most move slowly enough that people can move out of the way. The speed at which lava moves across the ground depends on several factors, including (1) type of lava erupted and its viscosity; (2) steepness of the ground over which it travels; (3) whether the lava flows as a broad sheet, through a confined channel, or down a lava tube; and (4) rate of lava production at the vent.

Low-silica basalt lava can form fast-moving (10 to 30 miles per hour) streams or can spread out in broad thin sheets up to several miles wide. Since 1983, Kilauea Volcano on the Island of Hawaii has erupted basalt lava flows that have destroyed more than 200 houses and severed the nearby coastal highway.

In contrast, flows of higher-silica andesite and dacite lava tend to be thick and sluggish, traveling only short distances from a vent. Dacite and rhyolite lavas often squeeze out of a vent to form irregular mounds called lava domes. Lava domes often grow by the extrusion of many individual flows >30 m thick over a period of several months or years. Such flows will overlap one another and typically move less than a few meters per hour.


Pyroclastic Flows

Pyroclastic flows descend the south-eastern flank of Mayon Volcano, Philippines.
Source: http://volcanoes.usgs.gov/Imgs/Jpg/Mayon/32923351-020_large.jpg

High-speed avalanches of hot ash, rock fragments, and gas can move down the sides of a volcano during explosive eruptions or when the steep side of a growing lava dome collapses and breaks apart. These pyroclastic flows can be extremely hot and move at speeds of 100 to 150 miles per hour. Such flows tend to follow valleys and are capable of knocking down and burning everything in their paths. Lower-density pyroclastic flows, called pyroclastic surges, can easily overflow ridges hundreds of feet high.

The climactic eruption of Mount St. Helens on May 18, 1980, generated a series of explosions that formed a huge pyroclastic surge. This so-called "lateral blast" destroyed an area of 230 square miles. Trees 6 feet in diameter were mowed down like blades of grass as far as 15 miles from the volcano.

How collapse of a growing lava dome generates the nuée ardente.
Source: http://www.geology.sdsu.edu/how_volcanoes_work/Images/Diagrams/PFDomeCollaps_crop_med.GIF

Pyroclastic flows erupted by Mount Pinatubo on June 15, 1991,
buried the Marella River valley with pumice, ash, and other volcanic rocks
Source: http://volcanoes.usgs.gov/Imgs/Jpg/PFeffects/3041135-092_large.JPG

Tephra and Ash Fall

Tephra is a general term for fragments of volcanic rock and lava regardless of size that are blasted into the air by explosions or carried upward by hot gases in eruption columns or lava fountains. Such fragments range in size from less than 2 mm (ash) to more than 1 m in diameter. Large-sized tephra typically falls back to the ground on or close to the volcano and progressively smaller fragments are carried away from the vent by wind. Volcanic ash, the smallest tephra fragments, can travel hundreds to thousands of kilometers downwind from a volcano.

Tephra consists of a wide range of rock particles (size, shape, density, and chemical composition), including combinations of pumice, glass shards, crystals from different types of minerals, and shattered rocks of all types (igneous, sedimentary, and metamorphic). A great variety of terms are used to describe the range of rock fragments thrown into the air by volcanoes. The terms classify the fragments according to size, shape, or the way in which they form and travel.

Tephra deposit about 9 cm thick blankets former U.S. Clark Air Base, Philippines, about 25 km east of Mount Pinatubo.
Source: http://volcanoes.usgs.gov/Imgs/Jpg/Pinatubo/16112441-008_large.jpg

Classification of Volcano: Eruption Style Pt 2 (Final)

Peléean eruptions

Pyroclastic flow resulted from the eruption of Mt. Pelée at 1902.
Source: http://volcano.und.edu/vwdocs/volc_images/north_america/XXVI.jpg

These eruptions involve viscous magma and shares characteristics with Vulcanian eruptions. They are usually violent and destructive and hence usually resulting in much of the volcano being blown apart. They occur when the gas is highly sticky magma builds up tremendous pressure. This pressure results in a large quantity of gas, dust, ash, and incandescent lava fragments being blown out of a central crater, fall back, and form tongue-like, glowing avalanches that move downslope ("nuées ardentes") at velocities as great as 100 miles per hour. Some of these eruptions may produce domes or short flows or ash and pumice cones. This type of eruption was first described at Mt. Pelée.

Vulcanian Eruptions

An ash-rich vulcanian eruption plumerises above Sabancaya volcano in northern Perú on April 15, 1991.
Source: http://www.volcano.si.edu/world/tpgallery.cfm?category=Pyroclastic%20Fall&photo=047076

Vulcanian eruptions are characterised by the eruption of solid rock and steam. They initially occur as a series of discrete, canon-like explosions that are short-lived, lasting for only minutes to a few hours, often with high-velocity ejections of bombs and blocks. After which, the subsequent eruptions can be relatively quiet and sustained. The fragments deposited by the eruptions can be from ash to blocks in size and cold to incandescent in temperature.

These eruptions are more explosive as compared to Strombolian eruptions as the eruptive columns are normally within 5-10 km high. The amount of tephra produced is relatively small, but due to the explosive nature of the eruption, it is dispersed over a wide area.

Vulcanian eruptions are often connected to andesitic to dacitic magma. The viscous magma makes it difficult for the gases to escape, this leads to the build up of high gas pressure and results in explosive eruptions.

Plinian Eruptions

Klyuchevskaya eruption, Kamchatka in 1994
Source: http://www.geology.sdsu.edu/how_volcanoes_work/Images/Eruptions/Klyuchevskaya_crop_l.jpg

Plinian eruptions are explosive and are associated with volatile-rich dacitic to rhyolitic lava, which erupts from stratovolcanoes. The eruptions are highly variable, lasting from several hours to about 4 days. Although Plinian eruptions characteristically involve felsic magma, they can occasionally occur in fundamentally basaltic volcanoes where the magma chambers become differentiated and zoned to create a siliceous top.

Rather than producing the discrete explosions that are typical of Vulcanian and Strombolian eruptions, Plinian eruptions generate sustained eruptive columns. Although they differ markedly from non-explosive Hawaiian eruptions, Plinian eruptions are similar to Hawaiian fire fountaining in that both of these eruption types generate sustained eruption plumes. In both, the eruption plumes are maintained because the growing bubbles rise at about the same rate as the magma moves up through the central vent system.

Plinian eruptions generate large eruptive columns that are powered upward partly by the thrust of expanding gases, and by convective forces with exit velocities of several hundred meters per second. Some reach heights of ~45 km. These eruptive columns produce widespread dispersals of tephra which cover large areas with an even thickness of pumice and ash. The region of pyroclastic fall accumulation is generally asymmetric around the volcano as the eruptive column is carried in the direction of the prevailing wind.

Most of the composite volcanoes tend to erupt in this manner. Fast-moving deadly pyroclastic flows, also known as nuées ardentes, are also commonly associated with Plinian eruptions.

Classification of Volcano: Eruption Style Pt 1

The eruptive style of a volcano is based on:

• Physical nature of the magma
• Character of explosive activity
• Nature of effusive activity
• Nature of dominant ejecta
• Structures built around vent

The five eruptive style are

• Hawaiian Eruptions
• Strombolian Eruptions
• Peléean Eruptions
• Plinian Eruptions
• Vulcanian Eruptions

Hawaiian Eruption

1984 eruption of Mauna Loa
Source: http://hvo.wr.usgs.gov/maunaloa/history/4305078_L.jpg

Hawaiin eruptions are the calmest of the eruption styles. They are characterized by the effusive emission of highly fluid and basaltic lavas with low gas contents. The volume of the ejected pyroclastic material is less than that of all the other eruption types. The characteristic of Hawaiian eruptions is the steady lava fountaining and the production of thin lava flows which eventually builds up to form large, broad shield volcanoes. Most of the eruption starts from fissures which come together to one or more central vents. The lava flows down away from the source vents in lava channels and lava tubes.

Strombolian Eruption

Strombolian activity on Mt. Etna in October 2002
Source: http://www.geology.sdsu.edu/how_volcanoes_work/Images/Pfeiffer/etna_strom02.jpg

Strombolian eruptions are named from the small volcanic-island of Stromboli, located between Sicily and Italy. The term “strombolian” has been used to describe a variety of volcanic eruptions that varies from small volcanic blasts, to kilometer-high eruptive columns. Strombolian activity is characterized by short-lived, explosive outbursts of pasty lava ejected a few tens or hundreds of meters into the air.

Strombolian eruptions never develop a sustained eruption column, unlike Hawaiian eruptions. The basaltic lava flows are relatively viscous. The gas pressure is also high as it is required to fragment the pasty lava, therefore resulting in periodic explosions with booming blasts. Although they are noisier as compared to Hawaiian eruptions, they are not more dangerous that it. Strombolian eruptions eject bomb sized and lapilli sized fragments that travels in a parabolic manner before it accumulates around the vent to construct the volcanic structure.

Classification of Volcano: Shape Pt 4 (final)

Acid or Dome Volcanoes

Internal structure of a typical lava dome
Source: http://pubs.usgs.gov/gip/volc/fig18.gif

Acid or dome volcanoes are steep-sided, convex cone because of the viscous (high silica content) lava which quickly cools and solidifies near the crater on exposure to air. The volcano grows largely by expansion from within, as indicated in the internal structure of the volcano by the layers of lava fanning upward and outward from the center. As it grows its outer surface cools and hardens. When part of a dome volcano collapses while it still contains molten rock and gases, it produces pyroclastic flow, one of the most lethal forms of volcanic event. Ultimately, many volcanic domes are destroyed by large explosive eruptions. Some domes form craggy knobs or spines over the volcanic vent, whereas others form short, steep-sided lava flows known as "coulees." Volcanic domes commonly occur within the craters or on the flanks of large composite volcanoes.

Volcanic dome atop Novarupta vent, Valley of Ten Thousand Smokes, Katmai National Park and Preserve, Alaska
Source: http://volcanoes.usgs.gov/Imgs/Jpg/Katmai/dds40-015_large.jpg

Next entry: Classification of Volcano by eruption style

Classification of Volcano: Shape Pt 3

Tephra Cone

Internal View of Tephra Cone volcano
Source: http://pubs.usgs.gov/gip/volc/fig8.gif

Cinder cones are the simplest type of volcano. They tend to be mainly explosive volcanoes, but they can also issue lavas. They are small volume cones consisting predominantly of tephra that result from eruptions consisting of rhyolitic and andesitic materials. They are actually fall deposits that are built surrounding the eruptive vent. They show an internal layered structure due to the varying intensities of the explosions that deposit different sizes of pyroclastics. They grow rapidly and soon reach their maximum size, not exceeding 250 meters in height and 500 meters in diameter, although some may rise to as high as 650 meters or more. Cinder cones can occur alone or in small to large groups or fields and most of them have a bowl-shaped crater at the summit. The gradual decrease in volume of the fallout materials (ash, lapilli) at greater distances from the vent leads to gentler slopes at the base of the cone. Cinder cones are commonly found in western North America as well as throughout other volcanic terrains of the world.

Pu`u ka Pele on the flanks of Mauna Kea, Hawaii
Source: http://volcanoes.usgs.gov/Imgs/Jpg/Photoglossary/30424305-084_large.JPG


Mt. Veniaminof in Alaska in its final stages of eruption in 1983-1984
Source: http://volcanoes.usgs.gov/Imgs/Jpg/Veniaminof/dds40-057_large.jpg

Classification of Volcano: Shape Pt 2

Composite Volcano or Stratovolcano

Cross-section of a typical Stratovolcano showing composite,
stratified nature with alternating layers of lava and tephra.
Source: http://pubs.usgs.gov/gip/volc/fig10.gif

Some of the Earth’s grandest mountains are composite volcanoes (aka stratovolcanoes). Stratovolcanoes show alternate layering of lava flows, tephra and volcanic ash, which is why they are called composite volcanoes. They are usually steep-sided, symmetrical cones of large dimension built of alternating layers of viscous andesitic lava flows, volcanic ash, cinders, blocks, and bombs and may rise as much as 8,000 feet above their bases. The high silica content of the magma results in it being viscous. It also makes gases trapped in it harder to escape, which frequently results in explosive eruptions. The steep slope near the summit is partially due to the thick, short viscous lava flows that are unable to travel far down the slope. The gentler base is due to the accumulation of material from the volcano and also pyroclastic material.

Most of the composite volcanoes have a crater at the summit which is formed by the explosive ejection of material from the central vent. Sometimes the craters have been filled in by lava flows or domes, or with glacial ice and less commonly they are filled with water.

The sequence of events for a violent eruption of Mount St. Helens, a composite volcano, in 1980. In the first photograph taken at 8:32:47, the original cone is intact, with some steam rising from the vent. The last photograph taken at 8:33:18,
shows the original cone blowing up.
Source: http://erg.usgs.gov/isb/pubs/teachers-packets/volcanoes/poster/graphics/posterfig6-7.jpg

Some of the most beautiful mountains in the world are composite volcanoes, including Mount Fuji in Japan (shown in the picture below), Mount Mayon in the Phillipines, Mount Cotopaxi in Ecuador , Mount Shasta in California, Mount Hood in Oregon and Mount Rainier in Washington.

Mount Fuji, Japan
Source: http://www.mt-fuji.co.jp/MMF/07/07feb.jpeg

Classification of Volcano: Shape Pt 1

Volcanoes can be classified based on their shape, their eruptive style and the tectonic environment. This entry will begin on classification of volcano through their shapes.

Shield Volcano

The Internal Structure of a Typical Shield Volcano
Source: http://pubs.usgs.gov/gip/volc/fig15.gif

Shield volcanoes form the largest volcanoes on Earth. They have gentle upper slopes and somewhat steeper lower slopes (somehow resembling a warrior’s shield, thus its name). It is built up slowly by the accretion of thousands of flows of low viscosity basalitic magma (which is very fluid) that easily spreads over great distances from the summit vent, then cooling as thin gently sloped sheets. The viscosity of magma is dependent on its temperature and composition. Shield volcanoes erupt magma as hot as 1,200 °C, compared with 850 °C for most continental volcanoes, which are usually composed of acidic lava. Because of the fluidity of the lava, major explosive eruptions do not occur in shield volcanoes. Lava also erupts from the vents along fractures that develop on the flanks of the cone. This gives the shield volcanoes the circular/oval shape with nearly flat summits.

The largest shield volcano, Mauna Loa volcano on the Island of Hawaii
Source: http://volcanoes.usgs.gov/Imgs/Jpg/Photoglossary/shieldvolcano1_large.jpg

Newberry Volcano, Oregon
USGS photo by Lyn Topinka

The Hawaiian Islands are composed of linear chains of the shield volcanoes. The islands are more than 15,000 feet above the ocean floor. For the Mauna Loa, the largest shield volcano, it is about 13,677 feet above sea level and its summit is 28,000 feet above the ocean floor. In Northern California and Oregon, many of the shield volcanoes have diameters of 3 or 4 miles and heights of 1,500 to 2,000 feet.