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Mudflow

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Mailboxes caught in a mudflow

A mudflow or mud flow is a form of mass wasting involving "very rapid to extremely rapid surging flow"[1] of debris that has become partially or fully liquified by the addition of significant amounts of water to the source material.[2]

Mudflowsi crfgeontain a significant proportion of clay, which makes them more fluid than debris flows; thus, they are able to travel farther and across lower slope angles. Both types are generally mixtures of various kinds of materials of different sizes, which are typically sorted by size upon deposition.[3]

Mudflows are often called mudslides, a term applied indiscriminately by the mass media to a variety of mass wasting events.[4] Mudflows often start as slides, becoming flows as water is entrained along the flow path; such events are often called flow slides.[5]

Other types of mudflows include lahars (involving fine-grained pyroclastic deposits on the flanks of stratovolcanoes) and jokulhlaups (outbursts from under glaciers or icecaps).[6]

Triggering of mudflows

The Mameyes mudflow disaster, in barrio Tibes, Ponce, Puerto Rico, was caused by heavy rainfall from Tropical Storm Isabel in 1985. The mudflow destroyed more than 100 homes and claimed an estimated 300 lives.

Heavy rainfall, snowmelt, or high levels of ground water flowing through cracked bedrock may trigger a movement of soil or sediments. Floods and debris flows may also occur when strong rains on hill or mountain slopes cause extensive erosion and/or what is known as "channel scour". The 2006 Sidoarjo mud flow may have been caused by rogue drilling.

Some broad mudflows are rather viscous and therefore slow; others begin very quickly and continue like an avalanche. If large enough, they can devastate villages and countrysides. They are composed of at least 50% silt and clay-sized materials and up to 30% water. Mudflows are common even in the hills around Los Angeles where they have destroyed many homes built on hillsides without sufficient support.

The point where a muddy material begins to flow depends on its grain size and the water content. Fine grainy material or soil has a smaller friction angle than a coarse sediment or a debris flow, but falling rock pieces can trigger a material flow, too.

On December 14, 1999 in Vargas, Venezuela, a mudflow known as The Vargas tragedy significantly altered more than 60 kilometers (37 mi) of its coastline; it was triggered by heavy rainfall and caused estimated damages of US$1.79 to US$3.5 billion, killed between 10,000 and 30,000 people, forced 85,000 people to evacuate, and led to the complete collapse of the state's infrastructure.

Mudflows and landslides

Landslide is a general term referring to all types of surface movement, particularly those involving the mass movement downhill of soil, rock or snow under the action of gravity. Landslides and avalanches can be devastating in terms of human life and general destruction.

Mudflows can be caused by unusually heavy rains or a sudden thaw. They consist mainly of mud and water plus fragments of rock and other debris, so they often behave like floods. They can move houses off their foundations or bury a place within minutes because of incredibly strong currents.

Every year, mudflows kill more people than typhoons, hurricanes and cyclones combined.[citation needed]

Mudflow geography

When a mudflow occurs it is given four named areas, the 'main scarp', in bigger mudflows the 'upper and lower shelves' and the 'toe'. The main scarp will be the original area of incidence, the toe is the last affected area(s). The upper and lower shelves are located wherever there is a large dip (due to mountain or natural drop) in the mudflow's path. A mudflow can have many shelves.

Largest recorded mudflow

The world's largest historic landslide (in terms of volume) occurred during the 1980 eruption of Mount St. Helens, a volcano in the Cascade Mountain Range in the State of Washington, USA. The volume of material displaced was 2.8 km³. Directly in the path of the huge mudflow was Spirit Lake. Normally a chilly 5°C, the lahar instantly raised the temperature to near 38°C. Today the bottom of Spirit Lake is 100 feet above the original surface. The lake now has two and a half times more surface area than it did before the eruption.[citation needed]

However, the world's largest known prehistoric terrestrial landslide took place in southwestern Iran, and is named the Saidmarreh Landslide. The landslide was located on the Kabir Kuh anticline in at 33 degrees N, 47.65 degrees E. The landslide had a volume of about 20 km³, a depth of 300 m, a travel distance of 14 km, and a width of 5 km. This means that about 50 billion tons of rock moved in this single event.[citation needed]

The largest known of all prehistoric landslides was an enormous submarine landslide that disintegrated 60,000 years ago and produced the longest flow of sand and mud yet documented on Earth. The massive submarine flow travelled 1,500 km – the distance from London to Rome.[citation needed]

Areas at risk

The area most generally recognized as being at risk of a dangerous mudflow are:

  • Areas where wildfires or human modification of the land have destroyed vegetation
  • Areas where landslides have occurred before
  • Steep slopes and areas at the bottom of slopes or canyons
  • Slopes that have been altered for construction of buildings and roads
  • Channels along streams and rivers
  • Areas where surface runoff is directed

Notes

  1. ^ 3 meters/minute to 5 meters/second; Hungr, Leroueil & Picarelli 2014, Table 2, citing Cruden and Varnes, 1996.
  2. ^ Hungr, Leroueil & Picarelli 2014, p. 185; Hungr, Leroueil & Picarelli 2013, p. 28.
  3. ^ Hungr, Leroueil & Picarelli 2014, pp. 170, 185.
  4. ^ Hungr, Leroueil & Picarelli 2013, p. 4.
  5. ^ Hunger, Leroueil & Picarelli 2013, §6.1 Flow slides; Hungr, Leroueil & Picarelli 2014, p. 167.
  6. ^ Hungr, Leroueil & Picarelli 2014, p. 185.

References

  • Hungr, Oldirch; Evans, S. G.; Bovis, M. J.; Hutchinson, J. N. (August 2001), "A review of the classification of landslides of the flow type", Environmental & Engineering Geoscience, 7 (3): 221–238, doi:10.2113/gseegeosci.7.3.221.
  • Hungr, Oldrich; Leroueil, Serge; Picarelli, Luciano (1 April 2014), "The Varnes classification of landslide types, an update", Landslides, 11 (2): 167–194, doi:10.1007/s10346-013-0436-y. On-line publication 30 November 2013.
  • Hungr, Oldrich; Leroueil, Serge; Picarelli, Luciano (4 January 2013), The Varnes classification of landslide types, an update. Draft of Hungr, Leroueil & Picarelli 2014, with page numbers.