Ash cloud from the 2008 eruption of Chaitén volcano streching across Patagonia from the Pacific to the Atlantic Ocean

Volcanic ash consists of small tephra, which are bits of pulverized rock and glass created by volcanic eruptions,^[1] less than in diameter.

How it is made

There are three mechanisms of volcanic ash formation: gas release under decompression causing magmatic eruptions; thermal contraction from chilling on contact with water causing phreatomagmatic eruptions and ejection of entrained particles during steam eruptions causing phreatic eruptions^[2]. The violent nature of volcanic eruptions involving steam results in the magma and solid rock surrounding the vent being torn into particles of clay to sand size.

Health & ecosystem effects (FAQ)

Volcanic ash can lead to breathing problems, malfunctions in machinery, and from more severe eruptions, years of global cooling.

Ash deposited on the ground after an eruption is known as ashfall deposit. Significant accumulations of ashfall can lead to the immediate destruction of most of the local ecosystem, as well the collapse of roofs on man-made structures.

Over time, ashfall can lead to the creation of fertile soils. Ashfall can also become cemented together to form a solid rock called tuff. Over geologic time, the ejection of large quantities of ash can produce an ash cone.

Composition

Particle of volcanic ash from Mount St. Helens

Table modified after^[2].

Ash is created when solid rock shatters and magma separates into minute particles during explosive volcanic activity. The usually violent nature of an eruption involving steam (phreatic eruption or phreatomagmatic eruption) results in the magma and solid rock surrounding the vent being torn into particles of clay to sand size.^[3]

Diamond Head, a well-known backdrop to Waikiki in Hawaii, is an ash cone that solidified into tuff

Spread

The plume that is often seen above an erupting volcano is composed primarily of ash and steam. The very fine particles may be carried for many miles, settling out as a dust-like layer across the landscape. This is known as an ashfall.^[4]

If liquid magma is ejected as a spray, the particles will solidify in the air as small fragments of volcanic glass. Unlike the ash that forms from burning wood or other combustible materials, volcanic ash is hard and abrasive. It does not dissolve in water, and it conducts electricity, especially when it is wet.

Ashfall can become cemented together by heat to form a solid rock called tuff.^[5] Ashfall breaks down over time, forming highly fertile soil, which has made many volcanic regions densely cultivated and inhabited despite the inherent dangers.^[6]

Atmospheric effects

Daytime Montserrat image during ash fall (1997)

Hong Kong sunset c. 1992 after the eruption of Mount Pinatubo.

Dangers

Rainbow and volcanic ash with sulfur dioxide emissions from Halema`uma`u vent.

Volcanic ash (by itself) is not poisonous, but inhaling it may cause problems for people whose respiratory system is already compromised by disorders such as asthma or emphysema. The abrasive texture can cause irritation and scratching of the surface of the eyes. People who wear contact lenses should wear glasses during an ashfall, to prevent eye damage. Furthermore, the combination of volcanic ash with moisture in the lungs can create a substance akin to liquid cement.

Therefore, people should take caution to filter the air they breathe with a damp cloth or a face mask when facing an ashfall. Ash is very dense, as only of ash leads to the collapse of weaker roofs. A fall of leads to the death of most vegetation, livestock, the wiping out of aquatic life in nearby lakes and rivers, and unusable roads.^[15] Accompanied by rain and lightning, ashfall leads to power outages, prevents communication, and disorients people.^[8]

Aviation

Ash plume from Mt Cleveland, a stratovolcano

Advisories concerning ongoing events

Increasing numbers of airplane incidents from atmospheric ash prompted a 1991 aviation industry meeting to decide how best to distribute information about ash events. One solution was the creation of Volcanic Ash Advisory Centers. There is one VAAC for each of nine regions of the world. VAACs can issue advisories and serve as liaisons between meteorologists, volcanologists, and the aviation industry.^[17]

See also

• Azomite
• Global dimming
• Pozzolana

References

External links

• A map of the 9 VAAC regions
• Ash Thickness and Particle Size Downwind from Mount St. Helens, Washington, on May 18, 1980
• Tephra Falls of the 1991 Eruptions of Mount Pinatubo
• What to do during an ash fall event
• Social & Economic Costs of Volcanic Ash to Aviation from "NOAA Socioeconomics" website initiative

Further reading

• U.S. Department of the Interior. U.S. Geological Survey. (1991). First international symposium on volcanic ash and aviation safety : program and abstracts : Seattle, Washington, July 8-12, 1991 [U.S. Geological Survey Circular 1065]. Denver: author.

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