Dust storm

A dust storm, also called sandstorm, is a meteorological phenomenon common in arid and semi-arid regions. Dust storms arise when a gust front or other strong wind blows loose sand and dirt from a dry surface. Fine particles are transported by saltation and suspension, a process that moves soil from one place and deposits it in another.

Seen from above, a sandstorm might not look as strong as it really is. Namib Desert (2017) 25°20′07″S 016°03′05″E
Dust storm
A sandstorm approaching Al Asad April 27, 2005.
EffectMay cause coughing and spread dust.

Drylands around North Africa and the Arabian peninsula are the main terrestrial sources of airborne dust. It has been argued that[1] poor management of the Earth's drylands, such as neglecting the fallow system, are increasing dust storm's size and frequency from desert margins and changing both the local and global climate, and also impacting local economies.[2]

The term sandstorm is used most often in the context of desert dust storms, especially in the Sahara Desert, or places where sand is a more prevalent soil type than dirt or rock, when, in addition to fine particles obscuring visibility, a considerable amount of larger sand particles are blown closer to the surface. The term dust storm is more likely to be used when finer particles are blown long distances, especially when the dust storm affects urban areas.

Causes

Animation showing the global movement of dust from an Asian dust storm.

As the force of wind passing over loosely held particles increases, particles of sand first start to vibrate, then to move across the surface in a process called saltation. As they repeatedly strike the ground, they loosen and break off smaller particles of dust which then begin to travel in suspension. At wind speeds above that which causes the smallest to suspend, there will be a population of dust grains moving by a range of mechanisms: suspension, saltation and creep.[2]

A study from 2008 finds that the initial saltation of sand particles induces a static electric field by friction. Saltating sand acquires a negative charge relative to the ground which in turn loosens more sand particles which then begin saltating. This process has been found to double the number of particles predicted by previous theories.[3]

Particles become loosely held mainly due to a prolonged drought or arid conditions, and high wind speeds. Gust fronts may be produced by the outflow of rain-cooled air from an intense thunderstorm. Or, the wind gusts may be produced by a dry cold front, that is, a cold front that is moving into a dry air mass and is producing no precipitation—the type of dust storm which was common during the Dust Bowl years in the U.S. Following the passage of a dry cold front, convective instability resulting from cooler air riding over heated ground can maintain the dust storm initiated at the front.

In desert areas, dust and sand storms are most commonly caused by either thunderstorm outflows, or by strong pressure gradients which cause an increase in wind velocity over a wide area. The vertical extent of the dust or sand that is raised is largely determined by the stability of the atmosphere above the ground as well as by the weight of the particulates. In some cases, dust and sand may be confined to a relatively shallow layer by a low-lying temperature inversion. In other instances, dust (but not sand) may be lifted as high as 20,000 feet (6,100 m) high.

Drought and wind contribute to the emergence of dust storms, as do poor farming and grazing practices by exposing the dust and sand to the wind.

One poor farming practice which contributes to dust storms is dryland farming. Particularly poor dryland farming techniques are intensive tillage or not having established crops or cover crops when storms strike at particularly vulnerable times prior to revegetation.[4] In a semi-arid climate, these practices increase susceptibility to dust storms. However, soil conservation practices may be implemented to control wind erosion.

Physical and environmental effects

Dust storm in Sahara, painted by George Francis Lyon

A sandstorm can transport and carry large volumes of sand unexpectedly. Dust storms can carry large amounts of dust, with the leading edge being composed of a wall of thick dust as much as 1.6 km (0.99 mi) high. Dust and sand storms which come off the Sahara Desert are locally known as a simoom or simoon (sîmūm, sîmūn). The haboob (həbūb) is a sandstorm prevalent in the region of Sudan around Khartoum, with occurrences being most common in the summer.

The Sahara desert is a key source of dust storms, particularly the Bodélé Depression[5] and an area covering the confluence of Mauritania, Mali, and Algeria.[6] Sahara dust is frequently emitted into the Mediterranean atmosphere and transported by the winds sometimes as far north as central Europe and Great Britain. [7]

Saharan dust storms have increased approximately 10-fold during the half-century since the 1950s, causing topsoil loss in Niger, Chad, northern Nigeria, and Burkina Faso. In Mauritania there were just two dust storms a year in the early 1960s, but there are about 80 a year today, according to Andrew Goudie, a professor of geography at Oxford University.[8][9] Levels of Saharan dust coming off the east coast of Africa in June 2007 were five times those observed in June 2006, and were the highest observed since at least 1999, which may have cooled Atlantic waters enough to slightly reduce hurricane activity in late 2007.[10][11]

Sydney shrouded in dust during the 2009 Australian dust storm.

Dust storms have also been shown to increase the spread of disease across the globe.[12] Virus spores in the ground are blown into the atmosphere by the storms with the minute particles and interact with urban air pollution.[13]

Short-term effects of exposure to desert dust include immediate increased symptoms and worsening of the lung function in individuals with asthma,[14] increased mortality and morbidity from long-transported dust from both Saharan[15] and Asian dust storms[16] suggesting that long-transported dust storm particles adversely affects the circulatory system. Dust pneumonia is the result of large amounts of dust being inhaled.

Prolonged and unprotected exposure of the respiratory system in a dust storm can also cause silicosis,[17] which, if left untreated, will lead to asphyxiation; silicosis is an incurable condition that may also lead to lung cancer. There is also the danger of keratoconjunctivitis sicca ("dry eyes") which, in severe cases without immediate and proper treatment, can lead to blindness.

Economic impact

Dust storms cause soil loss from the dry lands, and worse, they preferentially remove organic matter and the nutrient-rich lightest particles, thereby reducing agricultural productivity. Also, the abrasive effect of the storm damages young crop plants. Dust storms also reduced visibility affecting aircraft and road transportation. In addition dust storms also create problems due to complications of breathing in dust.[18]

Dust can also have beneficial effects where it deposits: Central and South American rain forests get most of their mineral nutrients from the Sahara; iron-poor ocean regions get iron; and dust in Hawaii increases plantain growth. In northern China as well as the mid-western U.S., ancient dust storm deposits known as loess are highly fertile soils, but they are also a significant source of contemporary dust storms when soil-securing vegetation is disturbed.

Researchers from Hacettepe University have reported that Saharan soil may have bio-available iron and also some essential macro and micro nutrient elements suitable for use as fertilizer for growing wheat. It has been shown that Saharan soil may have the potential of producing bioavailable iron when illuminated with visible light and also it has some essential macro and micro nutrient elements. In this study the impact of various growth media on development of some bread wheat (Triticum aestivum L.) and durum wheat (Triticum durum L.) cultivars have been investigated. As a four different nutrient media, Hewitt nutrient solution [1], illuminated and non-illuminated Saharan desert soil solutions and distilled water have been utilized. Shoot length (cm.seedling-1), leaf area (cm2 seedling-1) and photosynthetic pigments [chlorophyll a, chlorophyll b and carotenoids, mg ml-1 g fresh weight (g fw)-1] have been determined. The results of this study indicate that, wheat varieties fed by irradiated Saharan soil solution gave comparable results to Hewitt nutrient solution. [19]

Extraterrestrial dust storms

Dust storms are not limited to Earth and have been known to form on other planets such as Mars.[20] These dust storms can extend over larger areas than those on Earth, sometimes encircling the planet, with wind speeds as high as 60 miles per hour (97 km/h). However, given Mars' much lower atmospheric pressure (roughly 1% that of Earth's), the intensity of Mars storms could never reach the kind of hurricane-force winds that are experienced on Earth.[21] Martian dust storms are formed when solar heating warms the Martian atmosphere and causes the air to move, lifting dust off the ground. The chance for storms is increased when there are great temperature variations like those seen at the equator during the Martian summer.[22]

Dust storms on Mars
June 6, 2018[23]
November 25, 2012
November 18, 2012
Locations of the Opportunity and Curiosity rovers are noted
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See also

References

  1. Eslamian, Saeid; Eslamian, Faezeh (2017). Handbook of Drought and Water Scarcity: Management of Drought and Water Scarcity. CRC Press. ISBN 978-1-351-85113-8. Retrieved 4 December 2017.
  2. Squires, Victor R. "Physics, Mechanics and Processes of Dust and Sandstorms" (PDF). Adelaide University, Australia. Archived (PDF) from the original on 2015-06-05. Retrieved 2007-07-29.
  3. "Electric Sand Findings, University of Michigan Jan. 6, 2008". Eurekalert.org. 2008-01-07. Archived from the original on 2016-05-20. Retrieved 2016-12-04.
  4. "Dust Storms Chapter" (PDF). Emergency Management Plan. State of Oregon. Archived from the original (PDF) on 2013-10-21.
  5. Koren, Ilan; Kaufman, Yoram J; Washington, Richard; Todd, Martin C; Rudich, Yinon; Martins, J Vanderlei; Rosenfeld, Daniel (2006). "The Bodélé depression: A single spot in the Sahara that provides most of the mineral dust to the Amazon forest". Environmental Research Letters. 1 (1): 014005. Bibcode:2006ERL.....1a4005K. doi:10.1088/1748-9326/1/1/014005.
  6. Middleton, N. J.; Goudie, A. S. (2001). "Saharan dust: Sources and trajectories". Transactions of the Institute of British Geographers. 26 (2): 165. doi:10.1111/1475-5661.00013. JSTOR 3650666.
  7. Pericleous, Koulis; et al. (2006). "Airborne Transport of Saharan Dust to the Mediterranean and to the Atlantic". Environmental Modelling and Simulation. EMS-2006: 54–59. ISBN 9780889866171.
  8. Brown, Lester R. (June 27, 2007) ENVIRONMENT: Around the Globe, Farmers Losing Ground Archived 2016-12-20 at the Wayback Machine. ipsnews.net
  9. Brown, Lester R. "Losing Soil". Archived from the original on 2007-06-29. Retrieved 2007-06-29.
  10. Loney, Jim (August 9, 2007) Scientists examine African dust link to hurricanes Archived 2016-12-20 at the Wayback Machine. Reuters
  11. "NASA: Saharan Dust Has Chilling Effect on North Atlantic". Nasa.gov. December 2007. Archived from the original on 2017-05-31. Retrieved 2016-12-04.
  12. Griffin, D. W. (2007). "Atmospheric Movement of Microorganisms in Clouds of Desert Dust and Implications for Human Health". Clinical Microbiology Reviews. 20 (3): 459–77, table of contents. doi:10.1128/CMR.00039-06. PMC 1932751. PMID 17630335.
  13. Sandstrom, T; Forsberg, B (2008). "Desert dust: An unrecognized source of dangerous air pollution?". Epidemiology. 19 (6): 808–9. doi:10.1097/EDE.0b013e31818809e0. PMID 18854705.
  14. Park, Jeong Woong; Lim, Young Hee; Kyung, Sun Young; An, Chang Hyeok; Lee, Sang Pyo; Jeong, Seong Hwan; Ju, Young-Su (2005). "Effects of ambient particulate matter on peak expiratory flow rates and respiratory symptoms of asthmatics during Asian dust periods in Korea". Respirology. 10 (4): 470–6. doi:10.1111/j.1440-1843.2005.00728.x. PMID 16135170.
  15. Perez, Laura; Tobias, Aurelio; Querol, Xavier; Künzli, Nino; Pey, Jorge; Alastuey, Andrés; Viana, Mar; Valero, Natalia; González-Cabré, Manuel; Sunyer, Jordi (2008). "Coarse Particles from Saharan Dust and Daily Mortality". Epidemiology. 19 (6): 800–7. doi:10.1097/EDE.0b013e31818131cf. PMID 18938653.
  16. Lee, Hyewon; Kim, Ho; Honda, Yasushi; Lim, Youn-Hee; Yi, Seungmuk (2013). "Effect of Asian dust storms on daily mortality in seven metropolitan cities of Korea". Atmospheric Environment. 79: 510–517. Bibcode:2013AtmEn..79..510L. doi:10.1016/j.atmosenv.2013.06.046.
  17. Goudie, Andrew S. (2014). "Desert dust and human health disorders". Environment International. 63: 101–13. doi:10.1016/j.envint.2013.10.011. PMID 24275707.
  18. "Dust Between Tigris and Euphrates Rivers, Iraq". Earth Snapshot. March 3, 2012. Archived from the original on May 29, 2014. Retrieved 2013-11-20.
  19. Yücekutlu, Nihal; Terzioğlu, Serpil; Saydam, Cemal; Bildacı, Işık (2011)."Organic Farming By Using Saharan Soil: Could It Be An Alternative To Fertilizers?" (PDF). Hacettepe Journal of Biology and Chemistry. 39 (1): 29–38
  20. "Discovery Monitoring and Predicting Extraterrestrial Weather". National Science foundation. Archived from the original on 2014-12-11. Retrieved 2013-11-21.
  21. "The Fact and Fiction of Martian Dust Storms". National Aeronautics And Space Administration. Archived from the original on 2016-09-14. Retrieved 2015-09-18.
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  23. Wall, Mike (12 June 2018). "NASA's Curiosity Rover Is Tracking a Huge Dust Storm on Mars (Photo)". Space.com. Retrieved 13 June 2018.
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