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An '''aridity index''' (AI) is a numerical indicator of the degree of dryness of the climate at a given location. A number of [[aridity]] indices have been proposed (see below); these indicators serve to identify, locate or delimit regions that suffer from a deficit of available water, a condition that can severely affect the effective use of the land for such activities as agriculture or stock-farming.
 
==Historical background and indices==
 
At the turn of the 20th century, [[Wladimir Köppen]] and [[Rudolf Geiger]] developed the concept of a [[Köppen climate classification|climate classification]] where arid regions were defined as those places where the annual rainfall accumulation (in centimetres) is less than <math>R/2</math>, where:
 
* <math>R=2\times T</math> if rainfall occurs mainly in the cold season,
* <math>R=2\times T+14</math> if rainfall is evenly distributed throughout the year, and
* <math>R=2\times T+28</math> if rainfall occurs mainly in the hot season.
 
where <math>T</math> is the mean annual temperature in Celsius.
 
This was one of the first attempts at defining an aridity index, one that reflects the effects of the thermal regime and the amount and distribution of precipitation in determining the native vegetation possible in an area. It recognizes the significance of temperature in allowing colder places such as northern [[Canada]] to be seen as humid with the same level of precipitation as some tropical deserts because of lower levels of potential evapotranspiration in colder places. In the subtropics, the allowance for the distribution of rainfall between warm and cold seasons recognizes that winter rainfall is more effective for plant growth that can flourish in the winter and go dormant in the summer than the same amount of summer rainfall during a warm-to-hot season. Thus a place like [[Athens, Greece]] that gets most of its rainfall in winter can be considered to have a humid climate (as attested in lush foliage) with roughly the same amount of rainfall that imposes semi-desert conditions in [[Midland, Texas]], where rainfall largely occurs in the summer.
 
In 1948, [[C. W. Thornthwaite]] proposed an AI defined as:
 
<math>AI_T = 100\times\frac{d}{n}</math>
 
where the water deficiency <math>d</math> is calculated as the sum of the monthly differences between precipitation and potential evapotranspiration for those months when the normal precipitation is less than the normal evapotranspiration; and where <math>n</math> stands for the sum of monthly values of potential evapotranspiration for the deficient months (after Huschke, 1959). This AI was later used by Meigs (1961) to delineate the arid zones of the world in the context of the UNESCO Arid Zone Research programme.
 
In the preparations leading to the UN Conference on Desertification (UNCOD), the [[United Nations Environment Programme]] (UNEP) issued a dryness map based on a different aridity index, proposed originally by [[Mikhail Ivanovich Budyko]] (1958) and defined as follows:
 
<math>AI_B = 100\times\frac{R}{LP}</math>
 
where <math>R</math> is the mean annual net radiation (also known as the net radiation balance), <math>P</math> is the mean annual precipitation, and <math>L</math> is the latent heat of vaporization for water. Note that this index is dimensionless and that the variables <math>R</math>, <math>L</math> and <math>P</math> can be expressed in any system of units that is self-consistent.
 
More recently, the UNEP has adopted yet another index of aridity, defined as:
 
<math>AI_U=\frac{P}{PET}</math>
 
where <math>PET</math> is the [[potential evapotranspiration]] and <math>P</math> is the average annual [[Precipitation (meteorology)|precipitation]] (UNEP, 1992). Here also, <math>PET</math> and <math>P</math> must be expressed in the same units, e.g., in milimetres. In this latter case, the boundaries that define various degrees of aridity and the approximate areas involved are as follows:
 
<center>
{|border=1 cellspacing=0 cellpadding=5
! Classification || Aridity Index|| Global land area
|-
|Hyperarid || AI < 0.05 || 7.5%
|-
|Arid || 0.05 < AI < 0.20 || 12.1%
|-
|Semi-arid || 0.20 < AI < 0.50 || 17.7%
|-
|Dry subhumid || 0.50 < AI < 0.65 || 9.9%
|}
</center>
 
==See also==
*[[Climate classification]]
*[[Savory brittleness scale]]
*[[Aridification]]
*[[Desertification]]
 
==References==
* Budyko, M. I. (1958) ''The Heat Balance of the Earth's Surface'', trs. Nina A. Stepanova, US Department of Commerce, Washington, D.D., 259 p.
* Huschke, Ralph E. (1959) ''Glossary of Meteorology'', American Meteorological Society, Boston, Second printing-1970.
* McIntosh, D. H. (1972) ''Meteorological Glossary'', Her Majesty's Stationery Office, Met. O. 842, A.P. 897, 319 p.
* Meigs, P. (1961) 'Map of arid zone', in [[Laurence Dudley Stamp|L. D. Stamp]] (Editor) ''A History of Land Use in Arid Regions'', UNESCO Arid Zone Research, Publication XVII, Paris, 388 p.
* UNCOD Secretariat (1977) ''Desertification: Its causes and consequences'', Pergamon Press, 448 p.
* UNEP (1992) ''World Atlas of Desertification''.
 
[[Category:Climatology]]
[[Category:Hydrology]]

Revision as of 12:39, 8 April 2013

An aridity index (AI) is a numerical indicator of the degree of dryness of the climate at a given location. A number of aridity indices have been proposed (see below); these indicators serve to identify, locate or delimit regions that suffer from a deficit of available water, a condition that can severely affect the effective use of the land for such activities as agriculture or stock-farming.

Historical background and indices

At the turn of the 20th century, Wladimir Köppen and Rudolf Geiger developed the concept of a climate classification where arid regions were defined as those places where the annual rainfall accumulation (in centimetres) is less than R/2, where:

  • R=2×T if rainfall occurs mainly in the cold season,
  • R=2×T+14 if rainfall is evenly distributed throughout the year, and
  • R=2×T+28 if rainfall occurs mainly in the hot season.

where T is the mean annual temperature in Celsius.

This was one of the first attempts at defining an aridity index, one that reflects the effects of the thermal regime and the amount and distribution of precipitation in determining the native vegetation possible in an area. It recognizes the significance of temperature in allowing colder places such as northern Canada to be seen as humid with the same level of precipitation as some tropical deserts because of lower levels of potential evapotranspiration in colder places. In the subtropics, the allowance for the distribution of rainfall between warm and cold seasons recognizes that winter rainfall is more effective for plant growth that can flourish in the winter and go dormant in the summer than the same amount of summer rainfall during a warm-to-hot season. Thus a place like Athens, Greece that gets most of its rainfall in winter can be considered to have a humid climate (as attested in lush foliage) with roughly the same amount of rainfall that imposes semi-desert conditions in Midland, Texas, where rainfall largely occurs in the summer.

In 1948, C. W. Thornthwaite proposed an AI defined as:

AIT=100×dn

where the water deficiency d is calculated as the sum of the monthly differences between precipitation and potential evapotranspiration for those months when the normal precipitation is less than the normal evapotranspiration; and where n stands for the sum of monthly values of potential evapotranspiration for the deficient months (after Huschke, 1959). This AI was later used by Meigs (1961) to delineate the arid zones of the world in the context of the UNESCO Arid Zone Research programme.

In the preparations leading to the UN Conference on Desertification (UNCOD), the United Nations Environment Programme (UNEP) issued a dryness map based on a different aridity index, proposed originally by Mikhail Ivanovich Budyko (1958) and defined as follows:

AIB=100×RLP

where R is the mean annual net radiation (also known as the net radiation balance), P is the mean annual precipitation, and L is the latent heat of vaporization for water. Note that this index is dimensionless and that the variables R, L and P can be expressed in any system of units that is self-consistent.

More recently, the UNEP has adopted yet another index of aridity, defined as:

AIU=PPET

where PET is the potential evapotranspiration and P is the average annual precipitation (UNEP, 1992). Here also, PET and P must be expressed in the same units, e.g., in milimetres. In this latter case, the boundaries that define various degrees of aridity and the approximate areas involved are as follows:

Classification Aridity Index Global land area
Hyperarid AI < 0.05 7.5%
Arid 0.05 < AI < 0.20 12.1%
Semi-arid 0.20 < AI < 0.50 17.7%
Dry subhumid 0.50 < AI < 0.65 9.9%

See also

References

  • Budyko, M. I. (1958) The Heat Balance of the Earth's Surface, trs. Nina A. Stepanova, US Department of Commerce, Washington, D.D., 259 p.
  • Huschke, Ralph E. (1959) Glossary of Meteorology, American Meteorological Society, Boston, Second printing-1970.
  • McIntosh, D. H. (1972) Meteorological Glossary, Her Majesty's Stationery Office, Met. O. 842, A.P. 897, 319 p.
  • Meigs, P. (1961) 'Map of arid zone', in L. D. Stamp (Editor) A History of Land Use in Arid Regions, UNESCO Arid Zone Research, Publication XVII, Paris, 388 p.
  • UNCOD Secretariat (1977) Desertification: Its causes and consequences, Pergamon Press, 448 p.
  • UNEP (1992) World Atlas of Desertification.