Thornthwaite climate classification

The Thornthwaite climate classification is a climate classification system created by American climatologist Charles Warren Thornthwaite in 1931 and modified in 1948.[1][2][3][4]

1931 classification

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Precipitation effectiveness
Humidity province Vegetation P/E index
A (Wet) Rainforest P/E > 127
B (Humid) Forest 64 ≤ P/E ≤ 127
C (Subhumid) Grassland 32 ≤ P/E ≤ 63
D (Semiarid) Steppe 16 ≤ P/E < 31
E (Arid) Desert P/E < 16
Temperature efficiency
Thermal province T-E index
A (Tropical) T-E > 127
B (Mesothermal) 64 ≤ T-E ≤ 127
C (Microthermal) 32 ≤ T-E ≤ 63
D (Taiga) 16 ≤ T-E < 31
E (Tundra) 1 ≤ T-E < 16
E (Frost) T-E = 0

Precipitation effectiveness

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Thornthwaite initially divided climates based on five characteristic vegetations: Rainforest, forest, grassland, steppe and desert. One of the main factors for the local vegetation is precipitation, but most importantly, precipitation effectiveness, according to Thornthwaite. Thornthwaite based the effectiveness of precipitation on an index (the P/E index), which is the sum of the 12 monthly P/E ratios. The monthly P/E ratio can be calculated using the formula:[3][5]

 

Temperature efficiency

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Similarly to precipitation effectiveness, Thornthwaite also developed a T/E index to represent thermal efficiency. Featuring six climate provinces: Tropical, mesothermal, microthermal, taiga, tundra and frost.[3][5]

The T-E index is the sum of the 12 monthly T-E ratios, which can be calculated as:

 , where t is the mean monthly temperature in °F.[6]

1948 modification

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After being criticized for making climatic classification complex, Thornthwaite switched vegetation with the concept of potential evapotranspiration (PET), which represents both precipitation effectiveness and thermal efficiency.[5] Estimated PET can be calculated using Thornthwaite's own 1948 equation.[2]

Thornthwaite developed four indices: the Moisture Index (Im), the aridity and humidity indexes (Ia/Ih), the Thermal Efficiency Index (TE) and the Summer Concentration of Thermal Efficiency (SCTE). Each of the four climatic types can be described by an English alphabet letter and are arranged exactly by the order shown previously.[5] The first two letters are used to describe the precipitation pattern and the last two are used to describe the thermal regime.[2] As an example, B3s2A’b’4 (Tracuateua) describes a wet (B3), megathermal (A’) climate with a large summer water deficit (s2) and which more than 48% but less than 52% of the potential evapotranspiration is felt in the summer (b’4).[7]

Moisture Index

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Moisture index (Im)
Classes Im Im criteria
A (Perhumid) A Im ≥ 100
B (Humid) B4 80 ≤ Im < 100
B3 60 ≤ Im <80
B2 40 ≤ Im < 60
B1 20 ≤ Im < 40
C (Subhumid) C2 (Rainy Subhumid) 0 ≤ Im < 20
C1 (Dry Subhumid) -20 ≤ Im < 0
D (Dry) D -40 ≤ Im < -20
E (Arid) E -60 ≤ Im < -40
Thermal Efficiency Index
Class Annual PET (mm)
A (Megathermal) A’ PET ≥ 1140
B (Mesothermal) B’4 1140 > PET ≥ 997
B’3 997 > PET ≥ 885
B’2 885 > PET ≥ 712
B’1 712 > PET ≥ 570
C (Microthermal) C’2 570 > PET ≥ 427
C’1 427 > PET ≥ 285
D (Tundra) D’ 285 > PET ≥ 142
E (Perpetual ice) E’ PET < 142
Summer Concentration of Thermal Efficiency
Sub-class SCTE (%)
a a’ SCTE < 48
b b’4 48 ≤ SCTE ≤ 51.9
b’3 52 ≤ SCTE < 56.3
b’2 56.3 ≤ SCTE < 61.6
b’1 61.6 ≤ SCTE < 68
c c’2 68 ≤ SCTE < 76.3
c’1 76.3 ≤ SCTE < 88
d d’ SCTE ≥ 88

The Moisture Index (Im) expresses the global moisture of the environment and is directly related with the aridity and humidity indexes. The driving factor in this system is the water budget of a region.[8] Humidity classes range from Arid to Perhumid (Thoroughly Humid).

This index can be calculated as  , where Ih and Ia are the humidity and aridity indexes, respectively.

Seasonal Variation of Effective Moisture

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The Seasonal Variation of Effective Moisture is described by two indexes: The Aridity Index (Ia), used in wet climates to identify and quantify the severity of drought conditions, and the Humidity Index (Ih), used in dry climates to identify and quantify the severity of wet conditions.[1] These indexes are represented by the equations:

 ,

 , where D is the annual water deficit, S is the annual water surplus, and PET is the annual potential evapotranspiration[2]

Furthermore, these indices are represented by four letters, which indicate the seasonal distribution of precipitation: r (constantly rainy), d (constantly dry), s (summer deficit or surplus) and w (winter deficit or surplus) and two numbers to indicate the severity.

Wet climates (A, B, C2) can be classified as:

  • r (Without or with low deficit) : 0 ≤ Ia < 16.7
  • s (Moderate summer deficit) : 16.7 ≤ Ia < 33.3 and the deficit in the summer is larger than in the winter
  • w (Moderate winter deficit) : 16.7 ≤ Ia < 33.3 and the deficit in the winter is larger than in the summer
  • s2 (Large summer deficit) : Ia ≥ 33.3 and the deficit in the summer is larger than in the winter
  • w2 (Large winter deficit) : Ia ≥ 33.3 and the deficit in the winter is larger than in the summer

Dry climates (C1, D, E) can be classified as:

  • d (Without or with low surplus) : 0 ≤ Ih < 10
  • s (Moderate summer surplus) : 10 ≤ Ih < 20 and the surplus in the summer is larger than in the winter
  • w (Moderate winter surplus) : 10 ≤ Ih < 20 and the surplus in the winter is larger than in the summer
  • s2 (Large summer surplus) : Ih ≥ 33.3 and the surplus in the summer is larger than in the winter
  • w2 (Large winter surplus) : Ih ≥ 33.3 and the surplus in the winter is larger than in the summer

The deficiency of water in the soil is calculated as the difference between the potential evapotranspiration and the actual evapotranspiration.[2]

Thermal efficiency

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The thermal efficiency index (TE) is defined as the annual potential evapotranspiration (PET)[2] and has five different classifications: Megathermal, mesothermal, microthermal, tundra and perpetual ice.

Summer Concentration of Thermal Efficiency

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The Summer Concentration of Thermal Efficiency (SCTE) is a measure of the summer's potential evapotranspiration and can be calculated as  , where PET1, PET2 and PET3 are the estimated values of PET for the three hottest consecutive months.[2]

References

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  1. ^ a b Feddema, Johannes J. (January 2005). "A Revised Thornthwaite-Type Global Climate Classification". Physical Geography. 26 (6): 442–466. Bibcode:2005PhGeo..26..442F. doi:10.2747/0272-3646.26.6.442. S2CID 128745497. Retrieved 5 September 2021.
  2. ^ a b c d e f g Andrade, José Alexandre (2019). "Balanço hídrico do solo pelo método de Thornthwaite-Mather e classificação racional dos climas de Thornthwaite" (PDF) (in Portuguese). Departamento de Ciências da Universidade de Évora.
  3. ^ a b c "Thornthwaite Climate Classification | Encyclopedia.com". www.encyclopedia.com. Retrieved 5 September 2021.
  4. ^ Aparecido, Lucas Eduardo de Oliveira; Rolim, Glauco de Souza; Richetti, Jonathan; Souza, Paulo Sergio de; Johann, Jerry Adriani (August 2016). "Köppen, Thornthwaite and Camargo climate classifications for climatic zoning in the State of Paraná, Brazil". Ciência e Agrotecnologia. 40 (4): 405–417. doi:10.1590/1413-70542016404003916. hdl:11449/178225.
  5. ^ a b c d "Thornthwaite Climatic Classification - UPSC". lotusarise.com. 28 January 2021. Retrieved 5 September 2021.
  6. ^ "Classification of Climates | Climatology | Geography". Geography Notes. 11 March 2017. Retrieved 5 September 2021.
  7. ^ Whesley Thiago dos Santos, Lobato; Gabriela Mourão de, Almeida; Antonio Maricélio Borges de, Souza; Bianca Machado de, Lima; Marcus José Alves de, Lima (2018). "balanço hídrico e classificação climática segundo thornthwaite para o município de tracuateua-pa"" (PDF). Ciência tecnologia e desenvolvimento rural: Compartilhando conhecimentos inovadores e experiências (in Portuguese). doi:10.31692/2526-7701.IIICOINTERPDVAGRO.2018.00060. Retrieved 5 September 2021.
  8. ^ "Thornthwaite Classification". agron-www.agron.iastate.edu. Retrieved 5 September 2021.