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Tropopause

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The tropopause extends to high altitudes in the tropical latitudes and extends to low altitudes in the polar latitudes.

The tropopause is the atmospheric boundary that demarcates the lowest two layers of the atmosphere of Earth- the troposphere and stratosphere- which occurs approximately 17 kilometres (11 mi) above the equatorial regions, and approximately 9 kilometres (5.6 mi) above the polar regions.[1]

Definition

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The atmosphere of planet Earth: The tropopause is between the troposphere and the stratosphere.

Rising from the planetary surface of the Earth, the tropopause is the atmospheric level where the air ceases to become cool with increased altitude and becomes dry, devoid of water vapor. The tropopause is the boundary that demarcates the troposphere below from the stratosphere above, and is part of the atmosphere where there occurs an abrupt change in the environmental lapse rate (ELR) of temperature, from a positive rate (of decrease) in the troposphere to a negative rate in the stratosphere. The tropopause is defined as the lowest level at which the lapse rate decreases to 2°C/km or less, provided that the average lapse-rate, between that level and all other higher levels within 2.0 km does not exceed 2°C/km.[2] The tropopause is a first-order discontinuity surface, in which temperature as a function of height varies continuously through the atmosphere, while the temperature gradient has a discontinuity.[3]

Location

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The troposphere is the lowest layer of the Earth's atmosphere; it starts at the planetary boundary layer, and is the layer in which most weather phenomena occur. The troposphere contains the boundary layer, and ranges in height from an average of 9 km (5.6 mi; 30,000 ft) at the poles, to 17 km (11 mi; 56,000 ft) at the Equator.[4][5] In the absence of inversions and not considering moisture, the temperature lapse rate for this layer is 6.5 °C per kilometer, on average, according to the U.S. Standard Atmosphere.[6] A measurement of the tropospheric and the stratospheric lapse rates helps identify the location of the tropopause, since temperature increases with height in the stratosphere, and hence the lapse rate becomes negative.

Since the tropopause responds to the average temperature of the entire layer that lies underneath it, it is at its maximum levels over the Equator, and reaches minimum heights over the poles. On account of this, the coolest layer in the atmosphere lies at about 17 km over the equator. Due to the variation in starting height, the tropopause extremes are referred to as the equatorial tropopause and the polar tropopause.

Variations of starting height were found to correspond with the thermal structure both above and below where tropopause was recognized. The beginning of tropopause was determined to have a positive correlation to tropospheric temperature anomalies and a negative correlation to stratospheric temperature anomalies.[7] However, since 1980 the tropopause has been warming while the stratosphere cools according to Integrated Global Radiosonde Archive V2 data from NOAA.[7]This impacts tropopause starting height as the value is related to the average temperatures of the layers above and below. Because of a shift in average temperatures- particularly in the troposphere- it is expected the initial height of tropopause will increase given the expansion of warm air in the layer below.[7]

Alternative Definitions

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Given that the lapse rate is not a conservative quantity when the tropopause is considered for stratosphere-troposphere exchanges studies, there exists an alternative definition named dynamic tropopause.[8] It is formed with the aid of potential vorticity, which is defined as the product of the isentropic density, i.e. the density that is measurable by using potential temperature as the vertical coordinate, and the absolute vorticity, given that this quantity attains quite different values for the troposphere and the stratosphere.[9] Instead of using the vertical temperature gradient as the defining variable, the dynamic tropopause surface is expressed in potential vorticity units (PVU, 1 PVU = 10-6 K m2 kg-1 s-1[10]). Given that the absolute vorticity is positive in the Northern Hemisphere and negative in the Southern Hemisphere, the threshold value should be considered as positive north of the Equator and negative south of it.[11] Theoretically, to define a global tropopause in this way, the two surfaces arising from the positive and negative thresholds need to be matched near the equator using another type of surface such as a constant potential temperature surface. Nevertheless, the dynamic tropopause is useless at equatorial latitudes because the isentropes are almost vertical.[10] For the extratropical tropopause in the Northern Hemisphere the WMO established a value of 1.6 PVU,[10]: 152  but greater values ranging between 2 and 3.5 PVU have been traditionally used.[12]

It is also possible to define the tropopause in terms of chemical composition.[13] For example, the lower stratosphere has much higher ozone concentrations than the upper troposphere, but much lower water vapor concentrations, so an appropriate boundary can be defined.

Additionally, a stability-based definition can be applied, in which the vertical gradient of potential temperature is used to identify where the chemical composition changes the most. This can be defined as potential temperature gradient tropopause, or PTGT.[14] In order to examine these stability metrics, the relationship between a low-stability troposphere and high-stability troposphere is used to analyze gradients in the transition layer. The composition change of O3 on this vertical gradient is also considered.[14] This strategy aims to overcome potential failures of more traditional systems with static stability observations.

Tropical Tropopause Layer Cold Trap

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In 1949 Alan West Brewer proposed that tropospheric air passes through the tropopause into the stratosphere near the equator, then travels through the stratosphere to temperate and polar regions, where it sinks into the troposphere. [15] This is now known as Brewer-Dobson circulation. Because gases primarily enter the stratosphere by passing through the tropopause in the tropics where the tropopause is coldest, water vapor is condensed out of the air that is entering the stratosphere. This ″tropical tropopause layer cold trap″ theory has become widely accepted. [16] This cold trap limits stratospheric water vapor to 3 to 4 parts per million. [17] Researchers at Harvard have suggested that the effects of Global Warming on air circulation patterns will weaken the tropical tropopause layer cold trap. [18]

Water vapor that is able to make it through the cold trap eventually rises to the top of the stratosphere, where it undergoes photodissociation into oxygen and hydrogen or hydroxide ions and hydrogen.[19] [20] This hydrogen is then able to escape the atmosphere. Thus, in some sense, the tropical tropopause layer cold trap is what prevents Earth from losing its water to space. James Kasting has predicted that in 1 to 2 billion years, as the Sun increases in luminosity, the temperature of the Earth will rise enough that the cold trap will no longer be effective, and so the Earth will dry out.[21]

Phenomena

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The tropopause is not a fixed boundary. Vigorous thunderstorms, for example, particularly those of tropical origin, will overshoot into the lower stratosphere and undergo a brief (hour-order or less) low-frequency vertical oscillation.[22] Such oscillation results in a low-frequency atmospheric gravity wave capable of affecting both atmospheric and oceanic currents in the region.[22]

Most commercial aircraft are flown in the lower stratosphere, just above the tropopause, during the cruise phase of their flights; in this region, the clouds and significant weather perturbations characteristic of the troposphere are usually absent.[23]

See also

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References

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  1. ^ "Layers of the Atmosphere | National Oceanic and Atmospheric Administration". www.noaa.gov. Retrieved 2025-04-15.
  2. ^ International Meteorological Vocabulary (2nd ed.). Geneva: Secretariat of the World Meteorological Organization. 1992. p. 636. ISBN 978-92-63-02182-3.
  3. ^ Panchev, S. (1985). Dynamic meteorology. Environmental fluid mechanics (in engbul). Dordrecht [Netherlands] ; Boston : Hingham, MA, U.S.A: D. Reidel Pub. Co. ; Sold and distributed in the U.S.A. and Canada by Kluwer Academic Publishers. ISBN 978-90-277-1744-3.{{cite book}}: CS1 maint: unrecognized language (link)
  4. ^ Hoinka, K. P. (1999). "Temperature, Humidity, and Wind at the Global Tropopause". Monthly Weather Review. 127 (10): 2248–2265. Bibcode:1999MWRv..127.2248H. doi:10.1175/1520-0493(1999)127<2248:THAWAT>2.0.CO;2.
  5. ^ Gettelman, A.; Salby, M. L.; Sassi, F. (2002). "Distribution and influence of convection in the tropical tropopause region". Journal of Geophysical Research. 107 (D10): ACL 6–1–ACL 6–12. Bibcode:2002JGRD..107.4080G. CiteSeerX 10.1.1.469.189. doi:10.1029/2001JD001048.
  6. ^ Petty, Grant W. (2008). A first course in atmospheric thermodynamics. Madison, Wisconsin: Sundog Publishing. ISBN 978-0-9729033-2-5.
  7. ^ a b c Meng, Lingyun; Liu, Jane; Tarasick, David W.; Randel, William J.; Steiner, Andrea K.; Wilhelmsen, Hallgeir; Wang, Lei; Haimberger, Leopold (2021-11-05). "Continuous rise of the tropopause in the Northern Hemisphere over 1980–2020". Science Advances. 7 (45). doi:10.1126/sciadv.abi8065. ISSN 2375-2548. PMC 8570593. PMID 34739322.
  8. ^ Andrews, David G.; Holton, James R.; Leovy, Conway B. (1999). Middle atmosphere dynamics. International geophysics series (3. print ed.). Orlando, Fla.: Acad. Pr. ISBN 978-0-12-058576-2.
  9. ^ Hoskins, B. J.; McIntyre, M. E.; Robertson, A. W. (1985). "On the use and significance of isentropic potential vorticity maps". Quarterly Journal of the Royal Meteorological Society. 111 (470): 877–946. Bibcode:1985QJRMS.111..877H. doi:10.1002/qj.49711147002.
  10. ^ a b c World Meteorological Organization (WMO); National Aeronautics and Space Administration (NASA); Administration, Federal Aviation; National Oceanic and Atmospheric Administration (NOAA); United Nations Environment Programme (UNEP); Commission, European; Bundesministerium für Forschung und Technologie. "Atmospheric ozone 1985 - volume I". library.wmo.int. Archived from the original on 2023-11-28. Retrieved 2025-04-15.
  11. ^ Hoinka, Klaus P. (1998). "Statistics of the Global Tropopause Pressure". Monthly Weather Review. 126 (12): 3303–3325. doi:10.1175/1520-0493(1998)126<3303:SOTGTP>2.0.CO;2. ISSN 0027-0644.
  12. ^ Zängl, Günther; Hoinka, Klaus P. (2001). "The Tropopause in the Polar Regions". Journal of Climate. 14 (14): 3117–3139. doi:10.1175/1520-0442(2001)014<3117:TTITPR>2.0.CO;2. ISSN 0894-8755.
  13. ^ Pan, L. L.; Randel, W. J.; Gary, B. L.; Mahoney, M. J.; Hintsa, E. J. (2004). "Definitions and sharpness of the extratropical tropopause: A trace gas perspective". Journal of Geophysical Research: Atmospheres. 109 (D23). doi:10.1029/2004JD004982. ISSN 2156-2202.
  14. ^ a b Tinney, Emily N.; Homeyer, Cameron R.; Elizalde, Lexy; Hurst, Dale F.; Thompson, Anne M.; Stauffer, Ryan M.; Vömel, Holger; Selkirk, Henry B. (2022). "A Modern Approach to a Stability-Based Definition of the Tropopause". Monthly Weather Review. 150 (12): 3151–3174. doi:10.1175/MWR-D-22-0174.1. ISSN 0027-0644.
  15. ^ Brewer, A. W. (Oct 1949). "Evidence for a world circulation provided by the measurements of helium and water vapor distribution in the stratosphere". Quarterly Journal of the Royal Meteorological Society. 75 (326): 351–363. Bibcode:1949QJRMS..75..351B. doi:10.1002/qj.49707532603.
  16. ^ Hasebe, F.; Inai, Y.; Shiotani, M.; Fujiwara, M.; Vömel, H.; Nishi, N.; Ogino, S.-Y.; Shibata, T.; Iwasaki, S.; Komala, N.; Peter, T.; Oltmans, S. J. (Apr 2013). "Cold trap dehydration in the Tropical Tropopause Layer characterised by SOWER chilled-mirror hygrometer network data in the Tropical Pacific". Atmospheric Chemistry and Physics. 13 (8): 4393–4411. Bibcode:2013ACP....13.4393H. doi:10.5194/acp-13-4393-2013. hdl:20.500.11850/67923.
  17. ^ Catling, David C.; Kasting, James F. (2017). Atmospheric Evolution on Inhabited and Lifeless Worlds. Bibcode:2017aeil.book.....C.
  18. ^ Bourguet, Stephen; Linz, Marianna (2023). "Weakening of the tropical tropopause layer cold trap with global warming". Atmospheric Chemistry and Physics. 23 (13): 7447–7460. Bibcode:2023ACP....23.7447B. doi:10.5194/acp-23-7447-2023. S2CID 259520137.
  19. ^ Lewis, B. R.; Vardavas, I. M.; Carver, J. H. (June 1983). "The aeronomic dissociation of water vapor by solar H Lyman α radiation". Journal of Geophysical Research. 88 (A6): 4935–4940. Bibcode:1983JGR....88.4935L. doi:10.1029/JA088iA06p04935.
  20. ^ Nicolet, Marcel (July 1984). "On the photodissociation of water vapour in the mesosphere". Planetary and Space Science. 32 (7): 871–880. Bibcode:1984P&SS...32..871N. doi:10.1016/0032-0633(84)90011-4.
  21. ^ Caldeira, K; Kasting, J F (December 1992). "The life span of the biosphere revisited". Nature. 360 (6406): 721–23. Bibcode:1992Natur.360..721C. doi:10.1038/360721a0. PMID 11536510. S2CID 4360963.
  22. ^ a b Shenk, W. E. (1974). "Cloud top height variability of strong convective cells". Journal of Applied Meteorology. 13 (8): 918–922. Bibcode:1974JApMe..13..917S. doi:10.1175/1520-0450(1974)013<0917:cthvos>2.0.co;2.
  23. ^ Petty 2008, p. 21.

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