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GENERAL CIRCULATION
Mean Characteristics
R Grotjahn, University of California, Davis, CA, USA
Copyright 2002 Elsevier Science Ltd. All Rights Reserved.
doi:10.1006/rwas.2002.0154
Grotjahn, RUniversity of California,Department of Land, Air, and Water Resources,Davis, CA 95616-8627, USA
Introduction
The atmosphere of the Earth has a diverse range ofmotions. The general circulation refers to the larger-scale motions that have horizontal length scalesgreater than 1000 km and persist for a season orlonger. In addition, this term includes all processesnecessary to explain sufficiently, or maintain directly,the large-scale circulation.
The general circulation encompasses more thansimply the movement of the air. Understanding thecirculation requires the examination of many otheratmospheric quantities. Large-scale circulations arecreated by imbalances in the radiation fields that leadto temperature gradients that the atmosphere tries toeliminate. The circulations that develop are limited byvarious physical constraints such as energy balance,mass balance, and angular momentum balance. So,while the primary scope of this article is to descibe themean properties of the circulation, it is also necessaryto consider related variables that are directly observed.The related variables reveal the constraints on thecirculation and the underlying laws of dynamics andthermodynamics. Other articles on the general circu-lation discuss how the circulation is maintained andhow it can be simulated.
The general circulation of the atmosphere hascomplex structure in all dimensions as it evolves overthe seasons. To make a discussion of this subjectmanageable, it is traditional to examine first theproperties of the general circulation when longitudinalaverages are taken. Longitude averages are commonlylabeled ‘‘zonal means.’’ Zonal means provide a usefulstarting point since many atmospheric variables havemuch symmetry in the longitudinal direction. Forexample, contours of temperature in the upper trop-osphere are oriented east–west to a large degree. Zonalmeans reduce the information that one needs to view
in order to visualize the circulation. However, zonalaverages miss important phenomena that can be seenin time averages. Time means reveal longitudinalvariations that must be taken into account in order tounderstand both the properties and the maintenanceof the zonal mean state.
The general circulation undergoes seasonal change.In many fields the seasonal change is much less in theSouthern Hemisphere. The difference arises becausethe middle latitudes in the Southern Hemisphere havea much higher fraction of ocean coverage than those inthe Northern Hemisphere. Land and ocean havedifferent thermodynamic properties: heating andcooling are more readily mixed through a greateramount of mass in the ocean than on land; and thealbedo of land can change drastically with season,unlike that of the ice-free ocean. These factors magnifyseasonal change over land.
The difference in middle latitude land coverage hasanother implication. There are more major mountainranges in the Northern Hemisphere. The mountains,together with differences that arise between land andsea areas, lead to more prominent planetary waves inthe Northern Hemisphere. In contrast, many fields inthe Southern Hemisphere tend to be more zonallyuniform.
Longitudinal Average Characteristics
Radiation and Temperature
A discussion of the general circulation usually startswith radiation, since the distribution of radiationabsorbed and emitted is the ultimate driving mecha-nism for the circulation.
The Earth (including its atmosphere, solid, andocean parts) absorbs radiation emitted by the Sun.While the Earth rotates about an axis that is tilted withrespect to the Sun, the Equator is perpendicular to theSun’s rays on an annual average. Simple geometry (seeFigure 1) shows that the amount of solar radiationreaching unit area on the Earth diminishes from theEquator to the poles. The amount of solar radiationabsorbed is influenced by the reflectivity of the Earth’ssurface, the amount of cloud cover, and the path lengththrough the atmosphere. On an annual average, theamount of radiation absorbed decreases greatly fromthe Equator towards each pole. The rate that absorp-tion decreases with latitude is greater in polar than intropical regions.
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The radiant energy absorbed is balanced by theenergy emitted by the Earth back to space. Like theabsorbed solar radiation, terrestrial emission alsodecreases from the Equator towards each pole on anannual average. The terrestrial emission is governedby the temperature and the radiative properties of theemitter. Emission comes from the surface of the Earthas well as from the atmosphere. For equivalentradiative properties, more radiant energy is emittedfrom objects that are hotter. Thus, the terrestrialemission is consistent with the tropics being warmerthan the polar regions. However, the emission does notchange with latitude nearly as fast as does theabsorption. There is therefore a net radiation surplusin the tropics and deficit in the extratropics. Apoleward energy transport is required, which hasimplications for the temperature field. The terrestrialemission means that temperatures are lower in thetropics and warmer in the polar regions than theywould be without heat transport. While some trans-port occurs via the oceans, the remainder occurs in theatmosphere, and so the atmosphere must have acirculation. Further complicating the issue, the atmos-phere may transport the heat by direct means (termedsensible heat transport) or by transporting water(termed latent heat transport). In the latter process
heat is gained or released through a phase change ofthe water. Thus, the distribution of radiation implieslinks to temperature, velocity, and moisture fields.
Temperature In the troposphere and lower strato-sphere, absorption and emission of radiation alters theair temperature at a rate of a few degrees per day. Thischange of air temperature is generally small comparedwith the difference between the equatorial regions andthe polar regions. Hence, the radiant energy absorp-tion and emission do not create large temperaturedifferences between the daylight and night sides of theEarth. Therefore, much about the atmosphere’s ther-mal structure is seen in a zonal mean.
Seasonal averages for winter and summer temper-ature are displayed in Figure 2. The following prop-erties are evident from the figure:
1. Temperature decreases with increasing height. Therate of decrease (equal to the opposite of the lapserate) is greater in the troposphere and notably lessin the stratosphere. Temperature increases withheight in the tropical lower stratosphere. The lapserate is less than the lapse rate for neutral stability;the atmosphere is therefore statically stable on thelarge scale.
2. The tropopause marks the boundary between thestratosphere and troposphere. The zonal meantropopause is not level, but ranges from 6–8 km inpolar regions to 16–18 km in the tropics.
3. In the troposphere, zonal mean temperature alongan isobaric surface decreases towards each pole.The rate of decrease (the meridional gradient) issmall in the tropics and larger in the middlelatitudes (30–601 N or S). The gradient is strongerduring winter, with the exception of the sharpgradient near the Antarctic coast. The temperaturechange from Equator to pole is also greater at thesurface than in the middle troposphere.
4. The coldest temperatures are in the winter polarregion and near the equatorial tropopause.
5. In much of the lower stratosphere, the zonal meantemperature gradient is reversed from the tropo-sphere. The reversal is evident in much of thetropics and middle latitudes. The main exceptionsare the higher latitudes and part of the SouthernHemisphere middle latitudes during winter.
Mass fields The temperature field is related to themass fields in several ways. For example, the hypso-metric equation demonstrates that the spacing be-tween isobaric surfaces is proportional to the meantemperature of the air between those surfaces. In thetroposphere, air is warmer in the tropics, thus thevertical distance between any two isobaric surfaces
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0154-F0001 Figure 1 Schematic diagram of solar radiation reaching the
Earth at an equinox. Inset: latitudinal distribution of incoming solar
(solid line), absorbed solar (short dashed line), and terrestrial
emission (dashed line). Data redrawn from Barkstrom B, Harrison
E, and Lee R III (1990) EOS Transactions 71(9): 249, 299, 304–
305.
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(the ‘thickness’) is larger than in the extratropics. Sincethe variation of surface pressure over the Earth israther small, this implies that the altitude of a constantpressure surface (200 mbar, say) on average increasesfrom Pole to Equator.
The zonal mean geopotential heights of the 500 and1000 hPa surfaces are shown in Figure 3. The500 mbar surface is representative of geopotential
height surfaces in much of the troposphere and lowerstratosphere. At 500 mbar, the geopotential heightsare greater in the tropical regions with lowest valuesnear the poles. The gradient between Equator and poleis strongest in the middle latitudes. The 1000 mbarheight pattern is representative of the mass field nearthe surface. The surface pattern is quite different fromlevels above: pressure is relatively low along the
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Environmental Prediction/National Center for Atmospheric Research (NCEP/NCAR) reanalysis data 1979–99.
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Equator and in middle latitudes; pressure is highest inthe subtropics.
Zonal Velocity
The zonal wind is directed positive when blowingtowards the east. Outside the equatorial region, themass and wind fields are in approximate geostrophicbalance. The meridional gradient seen in the tropo-spheric geopotential height fields implies a westerlywind that is stronger in middle latitudes. At thesurface, comparatively weak winds are expected.
The thermal wind relation states that vertical‘‘shear’’ of the zonal wind is proportional to themeridional gradient of temperature and inverselyproportional to the Coriolis parameter. The tempera-ture gradient in much of the troposphere is directedequatorward, an orientation implying westerly windshear. Since the tropospheric temperature gradient isstronger in middle latitudes, one expects the westerlyshear to be stronger there as well. The temperaturegradient reverses in the tropical and middle latitudes ofthe lower stratosphere, implying easterly shear. There-fore, one anticipates westerly winds to increase with
height in the troposphere and to decrease above it, inthe lower stratosphere. In short, the stronger westerlywinds tend to occur at tropopause level.
Another constraint on the zonal wind is angularmomentum balance. If the winds at the surface wereeverywhere westerly, say, then those winds wouldapply a net torque upon the surface of the Earth. A netwesterly torque would speed up the rotation of theEarth and the days would be getting shorter. However,the angular momentum of the Earth is essentiallyconstant. Thus the areas of easterly winds must bebalanced by areas of westerly winds at the surface.
The zonal mean of the zonal wind is shown in Figure4 for winter and summer. Areas that are shadedindicate easterly winds. The following properties areevident from the figure:
1. The surface winds are generally easterly in thetropics, which make up approximately half of thesurface of the globe. The surface winds are westerlyprimarily in the middle latitudes.
2. The winds generally gain a westerly componentwith elevation. For the tropical troposphere, the
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for June–August. NCEP/NCAR reanalysis data 1979–99.
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easterly wind decreases with increasing elevation.For much of the middle latitudes, the westerly windincreases with height until the tropopause. Abovethe tropopause, the shear reverses and westerliesdecrease with increasing height. The principalexception is the middle latitudes of the SouthernHemisphere in winter. These properties, includingthe exception, are anticipated from the tempera-ture gradients.
3. In the high-latitude winter stratosphere, westerlywinds increase with height. It is difficult to see with
the vertical coordinate chosen, but these westerlywinds are associated with the polar night jet. Thatjet reaches maximum speed in the upper strato-sphere (10–30 hPa level).
4. The subtropical jets are prominent maxima at themidlatitude tropopause. These jets are stronger andmigrate to a lower latitude in winter. In theSouthern Hemisphere during winter, strong windsof the polar night jet extend into the upper tropo-sphere, creating the impression that there are twotropospheric jets on upper-level isobaric charts.
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Meridional Circulations
The meridional wind is comparable in magnitude tothe zonal wind in many instances. However, if themeridional wind is geostrophic, then a zonal average isthe integral (with respect to longitude) of a longitudi-nal derivative. Unless a mountain is intercepted, thisintegral must be zero because the integral completes acircuit. Since the total wind is nearly in geostrophicbalance outside the tropics, the zonal mean meridionalwind is very small outside the tropics.
Since the observed lapse rate is less than the dryadiabatic lapse rate, it follows that vertical motionsare resisted. One consequence is that vertical motionsare far smaller in magnitude than are horizontalmotions on this large scale. Large-scale verticalmotion cannot be measured directly since it is smallerthan the errors of the observing systems. Verticalvelocity can be estimated indirectly from quantitiesthat are measured with some confidence. One proce-dure is to estimate the meridional winds from anequation for angular momentum balance and thendeduce a streamfunction in the meridional plane. Analternative procedure is to input observed fields into aprimitive equation general circulation model and letthe model deduce the vertical motion. The latterprocedure obtained the motions shown in Figure 5.
The zonal mean motions in the meridional planehave the following properties:
1. The motion is organized into distinct patternscommonly referred to as meridional cells. Themost prominent cells occur in the tropics and areoften called the ‘‘Hadley’’ cells. In the middlelatitudes of each hemisphere is found a weakercirculation, usually called the ‘‘Ferrel’’ cell.
2. The meridional cells are much stronger duringwinter both in terms of the areal extent they occupyas well as the vigor of the circulation. The winterHadley cell has significant flow across the Equator.
3. The Hadley cell circulates in an intuitive sense:Rising motion occurs where the atmosphere iswarmer, and sinking motion where it is cooler. Thetemperature distribution over the globe is staticallystable in the dry sense. However, in the lowertropical troposphere the air is very moist and nearlyneutral with respect to a psuedoadiabatic lapserate. The upward motion of the Hadley cell isdriven by latent heat release as water vapor isconverted into precipitation. Precipitation is there-fore expected to be a maximum in the tropics. Inorder to overcome the moist static stability andentrainment as air parcels rise into the uppertropical troposphere, the rising motion is embed-ded within thunderstorms. These thunderstormsoccupy a very small fraction (about 0.5%) of the
tropical surface area. Air parcels in the poleward-moving branch of the Hadley cell cool radiatively;as their potential temperature decreases, theseparcels sink.
4. In the Ferrel cell air appears to rise where temper-atures are cooler and sink where they are warmer.This Eulerian mean motion should not be confusedwith the actual paths of air parcels. In middlelatitudes parcel motions are strongly influenced bybaroclinic waves. When an average is taken arounda latitude circle at constant pressure the resultingmean has the sense given by the Ferrel cell. Such amean does not reflect the motions of air parcels. Onthe other hand, if an average is taken alongconstant entropy surfaces (isentropic coordinates),it reflects the nearly adiabatic motion in the eddies,and the resulting mean meridional circulation hasthe same sense on the Hadley circulation.
5. The radiative energy distribution requires a merid-ional circulation to transport heat poleward. Themeridional motions of the Hadley cell transport thesame mass poleward as southward (ignoring themass due to moisture). The Hadley cell has a netheat transport because the upper-level air hashigher moist static energy than does the lower-level air. In the case of the Ferrel cell, the frontalsystems have strong heat fluxes that can be deducedfrom westward tilts with height of the trough andridge axes of these waves.
Precipitation
Precipitation is linked to the general circulation inseveral ways. Figure 6 shows the zonal mean distribu-tion of precipitation. The largest precipitation occursin the tropics and is associated with the rising branchof the Hadley cells. In some seasons, two equatorialmaxima are found, the explanation for which becomesclear when time mean fields are considered. Wheresinking motion is seen in the meridional cells, precip-itation is suppressed. Secondary maxima occur inmiddle latitudes that are superficially linked to therising branch of the Ferrel cells, but are more properlyassociated with the extratropical cyclones.
Time Average Characteristics
Midlatitude Planetary Waves and Storm Tracks
The mass and temperature fields have significantlongitudinal variation. Away from the surface, thetime mean pattern is characterized by long waves. The500 hPa geopotential height (Figure 7) is typical of thetroposphere. Prominent troughs are seen near themidlatitude east coasts of Asia and North America.The temperature field beneath (e.g., at 700 hPa) also
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has troughs near these regions. A weaker geopotentialtrough occurs over the Mediterranean and north-westAfrica. At the base of each trough the height contoursare more closely spaced; from geostrophic balancewind speeds would be expected to be relativelystronger there. Ridges are found in between, mostprominently in north-western North America andEurope. In summer, the North American trough
remains visible owing to the Baffin and Greenlandice sheets.
Most of the weather in the middle latitudes iscreated by travelling frontal cyclones. These cyclonesinteract with the planetary wave pattern in variousways. Cyclones prefer to form, propagate and decay inspecific regions. Generally speaking, cyclogenesis isfavored in three types of regions: near the east coasts of
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continents, on the lee side of major mountain ranges,and where large-scale surface temperature gradientsare strong. Most of these regions coincide with thelocations of longwave troughs. The last type includesthe area south of Africa and much of the southernIndian Ocean. The cyclones generally progress east-ward and poleward as they evolve. In the NorthernHemisphere cyclones often merge with or supplant the‘semi-permanent’ Aleutian and Icelandic lows (Figure8). The storm tracks show up in the precipitation fields(Figure 9) as bands of heavier precipitation in themiddle latitudes across the oceans. Precipitation is alsoenhanced where westerlies encounter mountain rang-es of North America and western Europe.
Subtropical Highs
At the surface one finds prominent high-pressureregions in the subtropics (Figure 8). A three-waybalance between the pressure gradient, Coriolis, andturbulent drag forces implies divergence at a surfacehigh. Surface divergence is consistent with the sinking,and here it is the sinking branch of the Hadley cells.The sinking is apparent in Figure 10 as areas whereupper-level divergent winds converge. When longitudeis included, the subtropical highs have a clear prefer-ence for the eastern sides of the major ocean basins.The mechanisms felt to be responsible for this prefer-ence are associated with the colder ocean temperaturesat these longitudes. The colder temperatures fosterlow stratus clouds, which in turn create a net radiativecooling of the air. As the air cools, it sinks. The arealextent of the highs is influenced by other factors suchas the midlatitude storm tracks and tropical convec-tion. In summer, these factors allow much greater
expansion of the subtropical highs in the Northernthan in the Southern Hemisphere. The tropical con-vection, mainly equatorward and to the west of thesubtropical high, feeds the circulation supporting thehigh; this link is observable in the divergent winds.
Divergent Tropical Circulations
The zonal mean Hadley circulation implies vigorousupward motion near the Equator and that motion isdriven by precipitation. The time mean precipitation,Figure 9, has a clear preference for tropical land areasand regions of warmest sea surface temperature. Innorthern summer, precipitation is greatly enhancedover India, while at other longitudes it remains closerto the Equator, resulting in the double maximum seenin Figure 6. The upward motion has similar zonalvariation.
The Hadley cell upward motion is part of thedivergent winds of the tropics. Diverging arrows inFigure 10 imply rising motion below. Following thedivergent wind vectors appears to connect areas ofpreferred rising with the sinking above the subtropicalhighs. Some divergent winds are poleward and thusconsistent with the Hadley circulation at 200 mbar.The strongest areas of divergence in Figure 10 overlieSouth-east Asia and Indonesia and Amazonia. Innorthern summer, the South-east Asian Monsoon isprominent. The figure also shows prominent east–westmotion in the Pacific that is generally referred to as the‘‘Walker’’ circulation. The Walker circulation appar-ently connects sinking over the subtropical highs of theeastern Pacific with the far western Pacific precipita-tion. The rising air is fed by low-level convergence thatresults from ageostrophic motions that occur forrelatively low surface pressure. Observations show alarge correlation between heavier precipitation inIndonesia, lower pressure there, and stronger Pacificsubtropical highs.
Subtropical Jet Streams
Zonal variations of the subtropical jet streams arelinked to many of the phenomena discussed above.The time mean wind speed is plotted in Figure 11. Thejet streams have relative maxima near the east coasts ofAsia and North America. These maxima are muchstronger during winter. The height gradients arestronger there as well, consistent with geostrophicbalance. Stronger portions of the jet streams occur inthe middle latitudes of the Southern Hemisphere.Further south (near 601 S) is another maximum duringsouthern winter that extends into the high strato-sphere (where it becomes the polar night jet) on a timeaverage.
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0154-F0007 Figure 7 Time mean geopotential heights of 500 mbar surface for (A) December–February and (B) June–August. Interval is 100 m.
NCEP/NCAR reanalysis data 1979–99. Major extratropical cyclone storm tracks are also marked using dashed arrows; tails located in
regions preferred for cyclogenesis and heads in regions preferred for cyclolysis. The tracks are highly idealized and are deduced from
various sources, including: Simmonds I and Murray R (1999) Weather Forecasting 14: 878–891; Sinclair M (1995) Monthly Weather
Review 123: 1601–1619; Whitaker L and Horn L (1984) Journal of Climatology 4: 297–310.
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0154-F0008 Figure 8 Time mean sea level pressure for (A) December–February and (B) June–August. Interval is 5 mbar. NCEP/NCAR reanalysis
data 1979–99.
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0154-F0009 Figure 9 Time mean precipitation for (A) December–February and (B) June–August. Interval is 2 mm d�1. CMAP 1979–99 data used.
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0154-F0010 Figure 10 Time mean divergent wind (arrows) and velocity potential (contours) at 200 mbar during (A) December–February and (B)
June–August. The longest arrow is approximately 10 m s� 1 and the contour interval is 2� 106 m2 s2. NCEP/NCAR reanalysis data 1979–
99.
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0154-F0011 Figure 11 Time mean horizontal wind at 200 mbar for (A) December–February and (B) June–August. Interval is 5 m s� 1. NCEP/NCAR
reanalysis data 1979–99.
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The divergent winds of the Hadley cell advectplanetary angular momentum poleward and therebystrengthen the subtropical jets in preferred regions. Inthe case of east Asia, divergent flow northward fromthe Indonesia region during northern winter buildshigher pressure to the south east of the Asian longwavetrough. This amplifies the height gradient on thesouth-east side of that trough (e.g. Figure 7A). Thedivergent flow southward from the Indonesia regionleads to the stronger jet over Australia.
See also
Dynamic Meteorology: Balanced Flows and Potential-Vorticity Inversion (0140); Overview (0138); PrimitiveEquations (0139); Waves and Instabilities (0141). GeneralCirculation: Energy Cycle (0155); Overview (0153).General Circulation Models (0157). Hadley Circula-tion (0161). Middle Atmosphere: Zonal Mean Climatol-
ogy (0227). Monsoon: Overview (0235). PlanetaryAtmospheres: Mars (0312); Venus (0313). RadiationBudget: Planetary (0335). Synoptic Meteorology:Weather Maps (0397). Tropical Meteorology: TropicalClimates (0416).
Further Reading
Grotjahn R (1993) Global Atmospheric Circulations: Ob-servations and Theories. New York: Oxford UniversityPress.
Johnson DR (1989) The forcing and maintenance of globalmonsoonal circulations: An isentropic analysis. In: Ad-vances in Geophysics, Vol. 31, pp. 43–316. San Diego,CA: Academic Press.
Karoly DJ and Vincent DG (1998) Meteorology of theSouthern Hemisphere. Boston, MA: American Meteoro-logical Society.
Peixoto JP and Oort AH (1992) Physics of Climate. NewYork: American Institute of Physics.
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rwas.2002.0154 15/4/02 13:04 Ed:: M. SHANKAR No. of pages: 14 Pgn:: chris