Parameterization of moist convection in the ... - Wiley Online Library

JOURNAL

OF GEOPHYSICAL

Parameterization

RESEARCH,

of moist convection

VOL. 99, NO. D3, PAGES 5551-5568, MARCH

in the National

20, 1994

Center

for Atmospheric Research community climate model (CCM2) James J. Hack National Center for Atmospheric Research, Boulder, Colorado

Abstract. The National Center for Atmospheric Research (NCAR) community climate model (CCM) has historically made use of a moist adiabatic adjustment procedure for parameterizing the effects of moist convection. The most recent version of the NCAR CCM, CCM2, has abandoned this approach in favor of a stability-dependent mass-flux representation of moist convective processes. This scheme physically constrains the process of moist convection with the use of a simple bulk cloud model, which provides a basis for estimating convective-scale transports of heat, moisture, and other atmospheric constituents as well as the diabatic heating associatedwith condensation and the fallout of precipitation. This paper presents the formalism associated with this simple mass-flux approach and contrasts its behavior with the moist adiabatic adjustment procedure used in earlier models. The inclusion of this scheme significantly moistens and warms the model troposphere at all latitudes but particularly in the tropics. Additionally, the simulated magnitude, structure, and location of the largescale mean circulations are generally improved. The sensitivity of the simulated climate to the formulation of the cloud model is also presented. classes: moist adiabatic adjustment schemes [e.g., Manabe et al., 1965], moisture convergence schemes [e.g., Kuo, Observational studies have long since established the 1965, 1974; Anther, 1977; Donner et al., 1982], and Arfundamental role of moist convection in maintaining the akawa-Schubert schemes [e.g., Arakawa and Schubert, large-scale dynamical circulations in the tropics, which in 1974; Lord, 1982; Hack et al., 1984; Moorthi and Suarez, turn play an important role in the maintenance of the 1992]. More recently, a new generation of convective adjustatmospheric general circulation and climate [e.g., Riehl and ment [e.g., Bettr, 1986; Emanuel, 1991] and alternative Malkur, 1958; Lorenz, 1967; Newell et al., 1972]. Efforts to "mass-flux" approaches [e.g., Tiedke, 1989] have emerged properly incorporate the effects of moist convection in in the general circulation modeling community, further global-scale models are hampered by the wide range of broadening the range of parameterization techniques. Eximportant space and timescales occurring in the atmo- plicit treatment of the vertical mass transport attributable to sphere's general circulation. Because of computational cost, convective overturning is a common characteristic of massglobal numerical integrations of the governing atmospheric flux approaches. equations can only resolve the primary energetic and phePrevious versions of the National Center for Atmospheric nomenological scales of motion. Convective-scale pro- Research (NCAR) community climate model (CCM) have cesses, which are responsible for most of the phase change used the moist adiabatic adjustment procedure, which adand associated precipitation occurring in the atmosphere, justs the lapse rate of a saturated conditionally unstable are only of the order of several kilometers in scale and atmosphere to neutrality. Any water mass condensed in this therefore are contained in the truncated scales of motion. stratification process is immediately precipitated out of the Even though these processes occur below the resolvable system. This procedure is both simple and economical but scales of motion in a general circulation model, they never- ignores details of the physical processes associated with theless represent a very large, and often dominant, local moist convection, such as the details of vertical eddy transenergy source/sink in the climate system. port. Consequently, the utility of the scheme for investigatIt is argued that it should be possible to predict the time ing detailed interactions between convection and the largeevolution of the large-scale fields by describing only the scale motion field is extremely limited. For example, collective influence of the small-scale elements. Convective Albrecht et al. [1986] have demonstrated that the severe cold parameterization techniques seek to express the statistical bias exhibited by the NCAR CCM0 is attributable in part to contributionof these nonresolvableprocessesin terms of the the neglect of explicit penetrative eddy fluxes of water when explicitly resolved fields. Several interesting overviews on using a moist adiabatic adjustment approach. Such deficienthe subject of convective parameterization can be found in cies have provided a strong incentive to move toward a more the work of Frank [1983], Tiedtke [1988], and Cotton and comprehensive parameterization of moist convection in the Anther [1989]. In the past the most widely utilized convecNCAR CCM. tive parameterization methods have belongedto one of three Even the most sophisticated of cumulus parameterization Copyright 1994 by the American Geophysical Union. techniques lack the generality to treat the many types of moist convection that can occur in an atmospheric general Paper number 93JD03478. 0148-0227/94/93 JD-03478 $05.00 circulation model (e.g., convection not rooted in the bound1.

Introduction

5551

5552

HACK:

PARAMETERIZATION

OF MOIST

CONVECTION

ary layer). Consequently, these schemesoften rely on simple secondary convective adjustment procedures to deal with moist adiabatically unstable conditions remaining after their application. Ironically, these secondaryprocedurescan contribute significantlyto the large-scalethermodynamicbudget [e.g., Randall et al., 1989]. Thus their proper formulation should be of comparable importance to the formulation of the primary convective scheme. The motivation for the work presented in this paper was to formulate a minimal framework for parameterizing the process of moist convection in the NCAR CCM2. Our objectives were that the formulation

k-I

k+l

be suitable for use as either

the primary convective parameterization or as a secondary schemethat could be used in conjunction with another, more sophisticated,technique. Additionally, it was important that the scheme provide an estimate of the "sub-grid-scale" vertical mass exchange associatedwith the process of moist convection (e.g., to provide for a consistent treatment of constituent transport). In section 2 we present the detailed formalism for a simple stability-dependent mass flux approach that we believe satisfies these objectives. This scheme is used to parameterize moist convection in the NCAR CCM2, which is briefly described in section 3. In section 4 we illustrate the properties of this convection scheme by contrasting aspects of the CCM2 control climate with the climate produced by the CCM2 when using a moist adiabatic adjustment procedure. The details of the thermodynamic balance produced by each of the schemes,on both a global and a regional basis, will also be discussed.Finally, we show that although the mathematical approach for the simple mass flux scheme presented in section 2 is very similar to the moist convective adjustment procedure developed for the UCLA GCM by Arakawa and Mintz [1974], there are significant differences in their behavior. Once again, this comparison is made in the context of a long-term integration of the NCAR CCM2.

h• Figure 1. Conceptual three-level nonentraining cloud model. Tilde quantities represent "environmental" values.

terms in (1) and (2) are the major convective-scale contributors to the large-scalethermodynamic budget (i.e., horizontal eddy flux transports can be neglected). The barred quantities represent horizontal averages over an area large enough to contain a collection of cloud elements but small enough so as to cover only a fraction of a large-scale disturbance. By writing the mean thermodynamic variables in terms of their average cloud and environment properties and assuming that the convection occupies only a small fraction of the averaging area, the vertical eddy transports o)'s• and oo'(q' + l') can be approximatedby the difference between the upward flux inside a typical convective element and the downward flux (i.e., induced subsidence) in the environment [cf. Yanai et al., 1973]. Mathematically, this approximation takes the form 1

Fs,(p)=

(w's}) • -Mc(P)(g(p)

g

- Sc(P) + Ll(p)) (3)

2.

Mathematical

Formalism

1

The large-scale budget equations for dry static energy and total water

can be written

Fq+•(p) = --

g

(to'(q' +/')) -• -Mc(p)(cj(p)

as

- qc(P) - l(p))

• = -V. Vg at

op

Op

(w's•) + L• + cpQR

R.S.

op

( to' s}) + Lift

(4)

where Mc is a convective mass flux and Sc, qc, and l represent cloud-scale properties. Once again, note that the (1)

large-scaleenvironment is assumedto carry no liquid water. Thus (1) and (2) can be written as o

•= ot

-v.vq

op

op

ot

(to'(q' + 1')) - fit o

oq R.S.

op

(to'(q' + l')) - fit

ot

R.S.

+g

+

--=Fq+ 1--•. Ot Ot R.S.+g•pp

(2)

(5) (6)

Let us now turn our attention to a vertically discrete

wheres -= cpT + gz is the dry staticenergy;I represents model atmosphere (where the level index k decreases upliquid water; st -- s - LI is the static energy analog of the liquid water potential temperature introduced by Bens [1975]; • is the "convective-scale" rainwater sink; and QR is the net radiative heating rate. The subscriptR.S. denotes the resolvable-scale contributions to the large-scalebudget. Note that variations of the mean liquid water on the largescale are neglected. It is generally agreed that the remaining

ward) and consider the case where layers k and k + 1 are moist adiabatically unstable, i.e., a nonentraining parcel of

air at level k + 1 (with moist static energy h c) would be unstable

if raised to level k. We assume the existence

of a

nonentraining convective element with roots in level k + 1, condensationand rain out processesin level k, and limited detrainmentin level k - 1 (see Figure 1). In accordancewith

HACK: PARAMETERIZATION

(5) and (6) the discrete dry static energy and specifichumidity budgetequationsfor thesethree layers can be written as

•

=

Ot

Apk_ 1

{fima(Sc - Llk- •k_!)},

(7)

2

Ot

5553

where3'= (L/cp)(Oq*/OT'-)p andq} represents thesaturated specifichumidity.Assumingthat the large-scaleliquid water divergencein layer k is zero (i.e., there is no storageof liquid water in layer k), (16) can be manipulatedto give the rain-out term in layer k as

LRk-= L(1 - 13)mslk = (1 -/3)m s

g

•

OF MOIST CONVECTION

{ms(sc - Zk+!) 2

{

ß

- 13ms(s c- LIa- ga_lj) + LRa),

(8)

Sc +

l+y•

}

(h,.-

,

and the liquid water flux into layer k - 1 as (9)

• at = Ap•+• {ms(ga+•Sc)), •

Ot

=•

Apk_ •

13msLl k=13ms gk- s + c

(lO)

{/3ms(qc - qk_!)), 2

l+yk

(hc- •}) ß (19)

Equations(9) and (12) can be combinedto give an equation for the consumptionof moiststaticenergyin layer k + 1 by convection,

0q•

Ot

g

•Ap• {ms(qc - q•+•)-/3ms(qc - qk_!) - R•},

Oh•+•

2

(11)

ot

= Apk+• {ms(qk+« - qc)),

(12)

where the subscriptc denotescloud propertiesin the ascent region;q denotestotal water; ms is a convectivemassflux ,

1

parameter' at levelk - • thatwilltakea valuebetween 0

Ohc

(20)

where the approximationfollows from the assumptionthat Oh'/Otcan be neglected.Using the relation (1 + y•)(Og•/Ot)=

(O•/Ot), (8) can be manipulatedto give an expression for the time rate of change of saturated moist static energy in layer k

atthebottom ofthecondensation layer (level k + •, "cloud base"); and /3 is a yet to be determined "detrainment

#

• Ot = Ap•+1 ms(h•:+i•hc)• •Ot '

Off• gms

•= Ot

Apk

-

1

(1+ yk){(Scs•+•+ LI•)- fi(sc- •_1)}. 2

and 1. Thus the detrainmentparameteris a coefficienton the

convective mass fluxatlevel k + •, sothatthequantity flmB Subtracting(21) from (20) results in represents the convective massfluxthrough levelk - •. Note that the convective-scale

rainwater

sink •

has been

O(hc-[ a _ g(1+•'•)[(gkg•+•)tt(Scg•_l•)]}, (22)

redefined in terms of mass per unit area per unit time = msAp•,+• (h•+•- hc) Ot (denotedby R), and the resolvable-scalecomponentshave been dropped for the convenienceof the following discussion (i.e., the left-hand sides represent the large-scaleresponseto convective activity only). In the generalcase, the thermodynamicpropertiesof the from which the convective massflux ms can be written as

updraftregioncanbe assumedto be equalto their large-scale valuesin the subcloudlayer, level k + 1, plus somearbitrary thermodynamic perturbation, i.e.,

sc = gk+• + s',

(13)

qc = c7k+l+ q',

(14)

hc = Sc+ Lqc.

(15)

ms '--* ( Yk) - - •+ Ll•) = (h c - h Or Ap• [(Sc l_ h c] 1 [h•+• --•(Sc-•'k-l• )] Ap•+l

(23)

where r is a characteristicconvective adjustmenttimescale. Thus moist convection is possible anytime the numerator,

The perturbationquantitiesq' and s' are not an essential hc - if} > 0, and the convectivemassflux is directly componentof the schemebut in practiceare providedby the determined as a function of this stability measure. atmosphericboundarylayer (ABL) scheme(only for conPhysicallyrealistic solutionsrequire that the convective vective elements rooted in the boundary layer), as will be massflux ms be positive,implyingthe followingconstraint discussed

later.

on the detrainment parameter/3:

The liquid water generationrate at level k is given by the definition of the total water, qc

mslk = ms[qc- (qc)k]

(16)

where (qc)k is the specifichumidityin the ascentregionat

/3(1 + y•)(s c- •_!)2 < (1 + y•)(s c - s•+•+ - • Llk) Ap•

Ap•+l

(h•+•-hc).

(24)

level k. Using the saturation relation

(qc)k • q} + •

yk

l+ykL

1

- (hc - h k),

(17)

The CCM2 implementationimposestwo additionalphysical constraintson the procedure,which take the form of constraints on the detrainment parameter /3 [see Hack et al.,

5554

HACK:

PARAMETERIZATION

OF MOIST

CONVECTION

1993]. The first constraint does not allow the convection to

supersaturate the "detrainment layer," k - 1, while the second attempts to minimize the introduction of "2Ap" thermodynamic structures in the vertical. The constraint on supersaturationis not an intrinsic characteristic of the parameterization technique but is imposed because supersaturation of a model layer implicitly introduces the storage of liquid water on the large scale, somethingwhich the present CCM2 physics framework does not treat adequately (e.g., stable condensation would immediately remove such a supersaturated water mass). This constraint could be relaxed by generalizing the convection formalism to deal with liquid water in the "environment" coupled with the introduction of an explicit large-scaleliquid water transport capability (e.g., including the appropriate large-scale microphysicsformalism).

Figure 2. Method of successiveapplication of the cloud model shown in Figure 1, moving up one model layer with each application. See text for further discussion.

The discrete form of the total water budget (equations (10)-(12)) assumes that the total water flux and total mass

flux are linearly coupled, so that the detrainmentparameter /3 effectively determines the actual autoconversionof cloud water to rainwater. Thus the maximum detrainment,i•max,is determined from a minimum autoconversion requirement, which is mathematically written as

•

B max= max

,

1 - Co(SZ- t•Zmin)

(25)

budget equations (7)-(12) to complete the thermodynamic adjustment in layers k - 1 through k + 1. By repeated applicationof this procedurefrom the bottom of the model to the top, shifting up one discrete model layer at a time (see Figure 2), the thermodynamic structure is stabilized. Physically, the adjustment of a pair of layers further destabilizes the region immediately above, which is respondedto by the next application of the cloud model. A vertical profile of the

total cloud massflux, M c (whereMc•+•/2= mB•+•/2 +

where Co is a constantautoconversioncoetficient,/Szis the fima,+3/2) canbeconstructed andcanbeusedto estimate the depth of contiguousconvective activity (i.e., layers in which convective-scale transport of an arbitrary set of passive condensationand rain-out take place) including and below scalars. The free parameters for the scheme (and their layer k, and t•Zminis a minimum depth for precipitating default values) consist of a minimum convective detrainconvection.The first guessfor the detrainmentparameter,/3, merit, timin(0.10), a characteristicadjustmenttimescalefor comes from a crude buoyancy argument where

the convection, z (1 hour), a cloud water to rainwater

autoconversion coefficient Co (1.0 x 10-4 m-l), and a (26)

min1 (hc-•-•-l)Apk-1 This relation simply states that the maximum convective

massflux throughlevelk - j is linearlyreduced when negative buoyancy in layer k -

1 is diagnosed, subject to

some minimum detrainment•min' Thus the initial guessfor the detrainment parameter is a linear function the ratio of parcel buoyancy in the upper level of the cloud model to the parcel buoyancy in the condensation(or middle) level of the cloud model, subject to minimum and maximum bounds (e.g., determined from a minimum autoconversion of cloud water to rainwater). The physical constraints on the adjustment process,suchas positive massflux, are then applied to determine the actual value of fi appropriateto the stabilization of levels k and k + 1. The total convectiveprecipitation rate is then obtained by vertically integrating the convectivescale rainwater

sink

1

P=•

K

• Rk

PH20k=l

(27)

In summary, the convection procedure is applied as follows: a first guessat/3 is determined from (25) and (26) and further refined using (24). The convective mass flux, mB, is then determinedfrom (23), followed by applicationof

minimum depth for precipitating convection 8Zmin(0 m). We note that our formalism closely follows Arakawa [1969] and Arakawa and Mintz [ 1974], who use their procedure

to deal

with

middle-level

convection

in the UCLA

general circulation model (GCM) [see also Tokioka et al., 1984]. It can be shown that the mathematical formulation for

our approach reduces identically to the Arakawa and Mintz [1974] procedure when fi = 0. In physical terms our approach attempts to deal with moist instability by transporting water in the vertical (subject to some minimum autoconversion), whereas the Arakawa-Mintz procedure deals with suchinstability primarily through the condensationand rain out process. Thus the Arakawa-Mintz middle-level convection scheme is perfectly etficient with regard to the autoconversion of cloud water to rainwater. As we will show, this

simpledifferenceresultsin markedly different results, where the Arakawa-Mintz

scheme behaves

more like the Manabe

et al. [1965] moist adiabatic adjustment procedure.

3. Brief Description of the National Center for Atmospheric Research (NCAR) Community Climate Model (CCM2) The NCAR CCM2 representsan entirely new atmospheric general circulation model for which most aspects of the formulation represent improvements over the CCM1 [see Williamson et al., 1987; Hack et al., 1989]. The principal algorithmic approachescarried forward from CCM1 are the use of a semi-implicit, leap frog time integration scheme,the

HACK:

PARAMETERIZATION

use of the spectral transform method for treating the dry dynamics, and the use of a biharmonic horizontal diffusion operator. In most other respects the CCM2 makes use of new algorithms for both resolved dynamics and parameterized physics [see Hack et al., 1993]. The standard model configuration is run with a horizontal spectral resolution of T42 (2.8ø x 2.8øtransform grid), 18 vertical levels, and a top at 2.917 mbar. It employs a 20-min time step by dynamically adjustingthe spectral resolution of the top layer to maintain a Courant

number

of less than 1.

Two major improvements are included in the CCM2 dynamical formalism. The first is the incorporation of a hybrid vertical coordinate which is terrain following near the surface (traditional sigma) and transitionsto a pure pressure coordinate above about 100 mbar [Simmons and Stritfing, 1983]. The vertical finite difference approximationscollapse to those of CCM1 when the hybrid coordinate is set to be sigma. A second major change to the resolved dynamics is the incorporation of a shape-preserving semi-Lagrangian transport scheme [Williamson and Rasch, 1993] for advecting water vapor. This scheme can also be used to transport an arbitrary number of other scalar fields (e.g., cloud water variables, chemical constituents, etc.) as required by the application. The use of the SLT method largely addresses the many numerical problems exhibited by the spectral advection approach used in earlier versions of the CCM. The cloud fraction parameterization in CCM2 is a generalization of $1ingo [1987]. Clouds can form in any tropospheric layer except the lowest model level, and cloud fraction dependson relative humidity, vertical motion, static stability, and the convective precipitation rate. The cloud emissivities are determined from the local liquid water path, which is diagnosedby vertically integratinga specifiedliquid water concentration profile [see Kiehl et al., 1994]. The CCM2 treatment of longwave radiation remains much the same as in CCM1. The major changeis the incorporation of a Voigt line shape to more accurately treat infrared radiative cooling in the stratosphere [Kiehl and Briegleb, 1991]. The CCM2 also employs a &Eddington approximation to calculate solar absorption using 18 spectral intervals [Briegleb, 1993]. To incorporate the effects of clouds, the schememakes use of the cloud radiative parameterization of $1ingo [ 1989], where the optical properties for liquid droplet cloud particles are parameterized in terms of the liquid water path and effective radius. Comparisonswith available references suggestthat the scheme accurately captures radiative heating from the surface through the mesosphere(-75 km) with notable improvements in estimates of atmospheric absorption/heating below cloud decks. The &Eddington formulation also allows estimates of the photon flux necessary to compute photodissociationrates for chemistry applications and provides a versatile way to incorporate the effects of aerosols.

A diurnal cycle is incorporated in CCM2, for which both solar and longwave heating rates are updated every model hour, while the longwave absorptivities and emissivitiesare updated every 12 hours. Land and sea ice surfaces are modeled as horizontally homogeneousmedia with vertically varying thermal properties. The subsurfacetemperaturesare assumedto obey a thermal diffusion equation where the net energy flux at the surface/atmosphereinterface is calculated using bulk exchange formulae in which the transfer coefficients are stability dependent.

OF MOIST

CONVECTION

5555

A nonlocal ABL parameterization based on the work by Troen and Mahrt [1986] and Holtslag et al. [1990] is used in the NCAR CCM2 to represent turbulence in the atmospheric boundary layer. The parameterization scheme determines an eddy diffusivity profile based on a diagnosedboundary layer height and a turbulent velocity scale. It also incorporates nonlocal (vertical) transport by large eddies, thus providing a more comprehensive representation of the physics of boundary layer transport [Holtslag and Boville, 1993]. Subgrid-scale vertical transport of passive scalars by boundary layer turbulence is also treated. Above the ABL the local vertical diffusion scheme of CCM1 is retained although the functional dependence of the diffusion coefficients is somewhat different. McFarlane's [1987] parameterization of momentum flux divergence by stationary gravity waves is also included.

Finally, the simple mass flux scheme described in section 2 is used to represent all types of moist convection. The scheme also provides a consistent treatment of convective transports for an arbitrary number of passive scalars as required by the modelingapplication. The schememakes use of perturbation thermodynamic quantities, provided by the ABL scheme, to initiate convection within the diagnosed boundary layer. For example, the perturbation temperature is proportionalto (w' O•)o/Wm,where (w' 0•)0 is the surface virtual heat flux and w m is a convective velocity scale. The reader is referred to Holtslag and Boville [1993] for a more complete discussion. For the results discussed in later sections, the land surface

has specifiedfixed soil moisture properties. As in CCM 1, sea surface temperatures are specified by linear interpolation between the climatological monthly mean values but now use the data of $hea et al. [1990].

4.

Sensitivity of the CCM2 Climate

to Moist

Convection

In this section

we will

Formulation characterize

the behavior

of the

simple mass flux (hereafter referred to as SMF) scheme presented in section 2 by contrasting the mean control climate produced by the NCAR CCM2 with the climate produced using a conventional moist adiabatic adjustment procedure [e.g., Manabe et al., 1965]. The principal reasons for this comparison are the historical use of the moist adiabatic adjustment procedure in the NCAR CCM and its continuedwidespreaduse in atmosphericgeneral circulation modeling. The CCM2 control climate is derived from a 20-year seasonalcycle numerical integration for which many detailed aspectsare documented by Hack et al. [1994]. The detailed implementation of the moist adiabatic adjustment procedure follows Williamson et al. [1987]. The model climate using the moist adiabatic adjustment scheme is derived from a 5-year seasonalcycle numerical integration of the CCM2, the results of which will be referred to as the MAA experiment. The ordering of the discrete model physics is such that the stable condensation process always follows the convective parameterization in each of these experiments so that moist convective instability is treated first. Our discussion will focus principally on the mean thermodynamic structures and their maintenance for both the CCM2 and the moist adiabatic adjustment (MAA) experiments, with an emphasis on low-latitude behavior. The transient characteristics of the SMF scheme, some aspects

5556

HACK: PARAMETERIZATION

January Temperature

OF MOIST CONVECTION

servations, the simulated atmosphere continues to be slightly dry but well within 10% of the best available estimates(e.g., recent operationalanalysis,in situ observations, and satellite remote sensingmeasurements).As in the case of the zonally averaged thermal structure, the interannual

400.

variabilityof this field is very small.Althoughwe haveonly showncharacteristics of the Januarysimulation,the qualitative descriptionappliesequallywell to the July simulation

60t

[e.g., see Hack et al., 1994].

lOOt

80N

40N

0

405

805

Latitude(degrees)

ably well capturedin the CCM2 simulation.Anotherfeatureto note in thesediagrams,for later comparisonwith the MAA results,are the extensiveareasof low precipitationratesin the subtropics,particularly on the southernflank of the ITCZ.

January T Standard

Figure5 illustratesthe JanuaryandJulyprecipitationdistributionfor the CCM2 control.The majorprecipitation features, suchas the IntertropicalConvergenceZone (ITCZ), the midlatitudestormtracks, and the monsoonregimes,are reason-

Deviation

Thesesubtropicalsubsidence regionsare well definedby the precipitation field,whichrepresents a significant improvement over previous versions of the NCAR CCM.

The most seriousdeficienciesof the simulatedprecipitation field are a systematicoverestimateof precipitationover warm land areas, a "locking" of precipitationmaxima over steeporographicfeatures,and a tendencyto unrealistically concentrate precipitation over certain areas (e.g., New

Guineain Januaryand Central America in July). There is

80N

40N

0

40S

January

80S

Specific Humidity (g/kg)

Latitude(degrees) Figure 3.

(a) Zonally averaged January temperatureand

(b) the standarddeviationof the interannual variabilityin the zonally averagedJanuarytemperaturefor the National Cen-

ter for AtmosphericResearch(NCAR) communityclimate model(CCM)2. Contourintervalsare 5ø and 0.25ø, respectively, where shadingdenotes a standarddeviation exceeding 0.5øC.

;oo:

,ooo

of which are illustratedby Kiehl and Briegleb[1992]and

80N

Lieberman et al. [1993], will be documented in a future

40N

0

40S

80S

Latitude (degrees)

paper.All modelresultswill be presentedon modelhybrid surfaces(i.e., r/ surfaces,where r/is the definitionof the vertical coordinatewhich variesbetween0 and 1), whichfor practicalpurposesare nearly equivalentto the pressure

q Standard Deviation(g/kg) I"r.'.'.'.l.'.'.'.'.•'.'.'.••

....•........J.........4.. ......• ..... .[......• .......J'.'" • "-"E.... J .... 4...L•,,,•i,..... I

surfacessuggestedby the scalingof the ordinate. We begin by illustrating in Figures 3 and 4 the CCM2 zonally averaged mean thermal and moisture structuresand their variability (i.e., the interannual standard deviation of

the zonalaverage)for the monthof January.As shownby Hack et al. [1994],the CCM2 modelatmosphere is generally coldwhencomparedto globalobservational analyses,typically exhibitinga troposphericcoldbiasof 1øto 2øequatorward of 45ø, 2ø to 3ø at higher latitudes, and in excessof 8ø near the polar tropopause.Nevertheless, the CCM2 climate representsa marked improvement over previous versions

::

e

600

800

u

•ooo •,Th,, ' I ............................................. ' ' ' I ' ' ' I ' ' ' I ,....... " ' 80N

40N

0

40S

80S

Latitude(degrees)

which exhibited a broad-scale cold bias of some 30-8ø more.

Figure 4. (a) Zonally averagedJanuary specifichumidity Note that the standarddeviationof the interannualdeparand (b) the standarddeviationof the interannualvariability turesfrom the meanstateis very small,typifiedby only a in the zonally averagedJanuaryspecifichumidityfor the

few tenths of a degree at lower latitudes. The simulated NCAR CCM2. Contour intervals are 0.1, 0.5, 1.0, 2.0, moisturefield also representsan improvementover earlier 3.0,..., and0.1 g kg-], respectively. Shadingindicates versionsof the NCAR CCM. When comparedagainstob- regionswith valueslessthan0.01g kg-].

HACK:

PARAMETERIZATION

January Precipitation(ram/day) •so

•20w

sow

0

so[

•20[

•so

90N

60N

OF MOIST

CONVECTION

5557

The problem of precipitation "locking" is evident in both the January and the July simulation, over the Andes, Rocky 90N Mountains, central and eastern Equatorial Africa, and the Tibetan plateau. The orographic locking problem is not

60Nunique to theCCM2,asevidenced by theMONEGmodel

3ON

z0• intercomparison [World Climate Research Program (WCRP) 68, 1992] which suggesteda strong sensitivity in the

3OS

a0s This orographiclockingof precipitationcan have significant

60S

60s diabaticheatingassociated with the excessiveJuly precipi50s tationrate over the Tibetanplateauhelpsdrive an anoma-

0

precipitation distribution to therepresentation of orography. dynamical consequencesin the simulation. For example, the

90S

180

120W

•so

•20w

60W

0

60E

120E

lous local circulation which is a principal contributor to the relatively poor simulation of the Southeast Asian monsoon (e.g., the area of suppressedconvection over central India). The magnitude of these precipitation anomalies can be reduced somewhat with improved cloud diagnostics, but stationary features in the precipitation field remain and are

180

July Precipitation(mm/day) sow

0

so[

•20[

•so

90N asyet an unresolved aspectof the numerical simulation.

90N

Zonally and globally averaged precipitation characteristics 60N are shown in Figure 6. As in the case of the two-dimensional

60N

z0• precipitation distribution, thezonallyaveraged CCM2pre-

SON

cipitation rates exhibit many of the features contained in the observational estimates. These figures clearly show the ITCZ, the regionsof suppressedprecipitation on either flank 5OS of the ITCZ, and the midlatitude storm track regimes. The 60S •0s contribution to the total precipitation from the convective parameterization and from the stable condensation process 90S 90s (i.e., "grid-scale" release of latent heat) is also shown. Note 180 120W SOW 0 60E 120E 180 that the vast majority of the total precipitation is produced Figure 5. January and July precipitation distribution for by the convective parameterization scheme, particularly in the NCAR CCM2. The contour interval is 1, 2, 4, 8, 16, and the tropics. Although the global precipitation numbers are 0

32mmd-1. Shadedregions exceed4 mmd-1.

also direct evidence (the simulated strengthof the Australian monsoon) and indirect evidence (the characteristics of the simulated North Pacific 500-mbar stationary wave error, as discussedby Hack et al. [1994]) that the January western Pacific precipitation maximum may be anomalously shifted toward

the southwest.

The excessive continental precipitation is seen both in January, over South America, Northern Australia, and Indonesia, and in July, over most of North America, Central America, and Eastern Asia. This continental precipitation bias is generally associatedwith anomalously warm surface temperatures [see Hack et al., 1994]. Major contributors to the surfacetemperature bias and the associatedprecipitation bias are deficiencies in the diagnosisof cloud optical properties, as discussedby Kiehl [1994] and Hack [1994], as well as unrealistic

nonlinear

interactions

between

moist convec-

comparable to morerecentobservational estimates byLegate• and Willmott [1990]for the month of January, they significantly exceed these estimatesfor July. Excessive continentalprecipitation is a major contributor to the July global anomaly, although it is important to remember that there is substantial

uncertaintyin the globalobservationalestimates. We now move to the thermodynamic structures associated with the MAA experiment, which are illustrated in Figure 7 as departures from the CCM2 control integration (i.e., Figures 3 and 4). These figures show a model atmosphere that is systematically colder and dryer by as much as 4øCand

2 gmkg-• in thezonalaverage.Exceptions to thischaracterization are two shallow regions at high latitudes in the lower troposphere, which are somewhat warmer, and a shallow region near 900 mbar in the northern hemisphere subtropics,which is very slightly more moist. In general, the signal associated with these differences is substantially greater than natural internal variability. Typical changesare of the order of 3ø-4øC colder in the upper troposphere

tion andatmospheric boundarylayerprocesses, whichwe equatorward of 40ølatitudeandexceeding 0.5gmkg-• dryer will illustrate below. Secondary factors contributing to these biasesmay include the simple way in which the land surface is treated in the CCM2 control, an aspect of the simulation currently under investigation (see, for example, Bonan [1994]). Improved cloud diagnosticshelp reduce the magnitude of both the surface temperature and the precipitation anomalies as well as shift precipitation maxima closer to where they are observed, such as in the case of the simulated Australian monsoon. The shift in diabatic heating over the western Pacific also helps to improve deficiencies in the North Pacific January flow field.

from 900 through 500 mbar for the same latitude band. From a climate perspective the change in the vertically integrated specific humidity is quite significant. Figure 8 shows the zonally averaged, vertically integrated water vapor (or precipitable water) for CCM2, MAA, and the last 4 years of the European Centre for Medium-Range Weather Forecasts (ECMWF) operational analyses (i.e., since July

1988)for bothJanuaryand•luly(ascompiledby Trenberth [1992]). These figures clearly show how closely the CCM2 model climate correspondsto the operational analyses. The MAA experiment exhibits significant local departures (ex-

5558

HACK:

PARAMETERIZATION

January Precipitation

14 ß

13

' ' ' ' ' ' ' ' ' ' ' 'Oiob•l

..... ß --

12

......

11

Legal# and •lfillmoff CCU2Total CCU2Cenvee•ive CCM2Stable

3.83 mm/day 3.48 turn/day 2.83 mm/day 0.•5 mm/day

OF MOIST

CONVECTION

The January and July precipitation distributions for the MAA experiment are shown in Figure 9. Qualitatively, the .

overall

distribution

is similar

to the CCM2

control.

Once

again, there is evidence of excessive precipitation rates over warm land areas, although the magnitude of the most intense precipitation regions is noticeably decreased. For example,

10

the January precipitationmaximum over southernNew

9

Guinea is reduced by about 20% in the MAA experiment. This sort of reduction is symptomatic of an overall broadening of the precipitation features. One example of this is how the subtropicalprecipitation regimes are much less extensive and well defined. To some extent this may be related to a much less vigorous mean meridional (i.e., Hadley) circulation in the MAA experiment, which is not so effective at suppressing convection in the subtropical regions. This difference is also associated with the absence of an explicit convective-scale transport mechanisms, as we will show below. As in the CCM2 control, the July simulation shows clear evidence of precipitation locking over regionswith high

8 7 6 5 4

2 1

0 90

60

30

0

- 30

- 60

- 90

localized orography.Another feature of the January MAA simulation is a more vigorous and clearly defined Atlantic

Latitude

ITCZ.

The zonally and globally averaged MAA precipitation

July Precipitation

14

January

' ' ' ' ' ' ' ' ' ' ' '_Oiob•][

13

-

12

..... , ,

Legatesand Wlllmoff CC1•2Total ' CCU2Convective

[AT]

2.86 ram/day 3.81 ram/day 3.03 ram/day

200

11

10

9

8

.-....:.

7

..... :!-:::i:: .!:':

800

6 5

:":

1000

4

'-i:::•:. !.'-::::i:!:! i:::•:i:i::-'!'t.'"' ............... :............ i:!:•:i:i-i:?•:::i:•:. H es• ':

......

80N

40N

0

40S

80S

Latitude (degrees)

;3 2

January

[•]

1 0 go

Latitude

Figure 6. Zonally averaged January and July precipitation rates (convective, stable, and total) for the NCAR CCM2 and the observational estimates of Legates and Willmatt

o

?::::::.i :::::::::::::::::::::::::::::::::::::::::::::::::::::::::: ii:::::•i?:!::i::?:?::•!ii:•i::::•i:•i?,iiiii!i•

•'

:::::::::::::::::::::::::::::::::::::::::::::::::"j•::•?:%..-.,..-.....'!:i .......... ::•::ililiiii:' ........... •::•?:i::ii::i:'::i::!i!::!?:!:: ::i::•iii!•:%•

[1990]. ::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::: ......... ::::::::::::::::::::::::::::::::::::: -.!.-.--':.ili::ili?:::::::i::i

ceeding 5 kg m-2 in thezonalmean)andglobaldifferences,

1000

80N 40N 0 40S 80S when compared to either the analyses or the CCM2. Such Latitude (degrees) changes are not only important to the thermodynamic stability of the tropical atmosphere but have important "greenFigure 7. (a) Zonally averagedchangein temperatureand house" impacts on the clear-sky longwave radiative budget (b) zonally averaged change in specific humidity for the [e.g., Kiehl and Briegleb, 1992]. In global terms the change moist adiabatic adjustment (MAA) experiment. Contour in the top-of-atmosphereclear-sky longwave flux associated intervals are(a) 1øand(b) 0.1, 0.5, 1.0, 1.5,and2.0 g kg-•. with the difference in total precipitable water is comparable Lightest shading in Figure 7b depicts regions greater than to the change that would be associated with a doubling of -0.01 g kg-• , whilethedarkestshading denotes regions less ß

atmospheric C02, about4 w m-2.

than- 2.0 g kg- •.

HACK:

PARAMETERIZATION

OF MOIST

characteristics are illustrated in Figure 10, along with the 180 observational estimates of Legates and Willmott [1990]. Note the clear difference in the amplitude and zonal struc- son ture of the precipitation field when compared with the CCM2 control, even though the two experiments produce comparable global precipitation rates. For example, the MAA 30N experiment exhibits a broader and somewhat weaker ITCZ

in both Januaryand July, with a slightmeridionalshift

CONVECTION

5559

January Precipitation(ram/day) •2ow

eow

o

eo[

•2o•

180 90N

60N 3ON

0 305

30S

60S

60S

January Precipitable Water

so . . , . . , . . , . . 'Giob•lJ•v;ra•e-j sos 180 ..... œCItV• Af• -- •a2

5O

-----

90S

120W

60W

0

60E

120E

180

25.3kg/m t •.6 kg/•

•

•.O ke/•

July Precipitation(mm/day)

4O 180

120w

eow

0

eOE

120E

180

90N

90N

60N

60N

3ON

3ON

.

3O

2O

0

3OS

30S

60S

60S

10

90S

90S

o

180

60

90

•0

0

-•0

-60

120w

sow

0

eOE

120E

180

-90

Figure 9. January and July precipitation distribution for the MAA experiment. The contour interval is I, 2, 4, 8, 16,

Latitude

and32mmd-]. Shadedregionsexceed4 mmd-]. July Precipifable Water

toward the north in the January simulation. The most striking difference between the two experiments, however, is the partition of convective and stable precipitation, particularly in low latitudes. The equipartition of stable and convective rainfall in the MAA experiment is very similar to

6O

f' ' ' ' ' ' ' ' ' ' ' 'Giob•l ..... --

5O

œCIdWI r Analyuo8 CCId2

:28.8kg/mt 28.4 kg/m•

"

24.4kg/mz

the ratios observed in earlier versions of the NCAR 4O

of sensible heat.

3O

2O

10

o

CCM,

which also used the moist adiabatic adjustment procedure. As we will show, this characteristic appears to be attributable to the lack of explicit convective-scalevertical transport

[ I i I I I I I I I • , I t _I'""t' '••'' 90

60

30

0

-30

-60

-90

As shown earlier, the MAA model climate is both colder and dryer than the CCM2 model climate. Because of the large changesin these fields the MAA tropical atmosphere exhibits a significantlydifferent stability structure, as shown in Figure 11. The low-level thermodynamic structure for both the CCM2 and the MAA model climates are very similar and in reasonable agreement with more recent operational analyses. The most significant disagreement in the lower troposphere occurs in the very lowest levels of the

modelwhichturn out to be too dry whencomparedwith the

analyses. This deficiency may be attributable in part to an overly active atmospheric boundary layer, as we will show below. Above 850 mbar the thermodynamic structures are Figure. 8. Zonally averaged January and July precipitable water for CCM2, the MAA experiment, and from the Euro- quite different, where the larger departuresare dominatedby a much dryer model atmosphere in the MAA experiment. pean Centre for Medium-Range Weather Forecasts (ECMWF) analyses(January 1989-1992 and July 1988-1991). Two aspectsto note with respectto the CCM 1 model climate See text for additional discussion. are the large differencesin the low-level stability characterLatitude

5560

HACK:

PARAMETERIZATION

January Precipitation

14

ß.' ' ' ' ' ' ' ' ' ' ' 'Oiob•l ..... - --

12 11

Legal# and Willmoll IdAATotal • Conveefivo MAAS•able

......

3.83 ram/day "l 3.36 mm/day ß 1.72 ram/day 1.eX ram/day ß

ß

ß

lO ß

8 ß

7

,, .

.

.

.

.

$ .

.

,'

4

2 1

o

60

9o

30

0

- 30

- 60

- go

Latitude

July Precipitation

14

ß i

i

i

' ' ' ' ' '

13

Legates and Willmatt

12

Id• To•al MJul, Conve•'lve

11

i

,

i

Oiob•l Xve'm•e-I 2.86 ram/day

-I

3.86 mm/day 1.•7 ram/day

OF MOIST

CONVECTION

structure of two climatologically different regimes in the tropics for which there are high-quality in situ observations. The Yap atoll is located in a very active region of deep convection in the western Pacific while Ascension Island, located in the eastern Atlantic, is more typical of a suppressed convective regime. Three sets of data are shown in the main panels: radiosonde observations, for which the standarddeviation of the interannualmean is depictedusing error bars, profiles from the CCM2 model climate (solid curves), and profiles from the MAA model climate. These profiles show how well the CCM2 model climate compares with the actual observational record for these regions and how much the simulation degrades when using the moist adiabatic adjustment procedure. The contrast between the CCM2 and the MAA results is quantified in the side panels which show the CCM2-MAA temperature differences and the ratio of the MAA specifichumidity to the CCM2 specific humidity as functions of pressure. The MAA results are systematicallycolder in the middle to upper troposphereby 30-4ø and from 20% to 60% dryer in both regimes. Another feature is the improved tropopause definition in the CCM2 results, which can be seen in the sharp gradient in the temperature differences shown in Figure 12. These results show that the zonal mean differences illustrated in Figure 7 are fairly robust acrossthe various climatologicalregimesin the tropics, particularly with regard to the temperature bias. The lower tropospheric dry bias tends to be slightly dominated by the subsidenceregions where the moist adiabatic adjustmentschemeis most deficientat moisteningthe atmosphere in the vicinity of the trade inversion. The zonally averaged January convective-scale heating and moistening rates for the CCM2 and MAA experiments are shown in Figures 13 and 14, respectively. The physical processes contributing to these tendencies include moist convection and stable condensation. Other important diabatic effects not represented in these figures are the vertical

Id• Stable 1.89 ram/day

lO -

,

g

8 7 6

5 4

3 2

.

1

_•,,•'_•.;'/ ,-.

o go

I ••_ '... "" ß "-"' ," ': '•....:'•,"•7 .... :\ _j?:,,•. •= _/.,.'"•-•:-.,.j.::-' ',,.

i

-•_.-'

i

i

60

I

!

•

i

50

i

•

i

0

..'

i

i

':_•

i

- 50

i

lOO •.'.

200

i

- 60

- 90

Latitude

300

400 500

Figure 10. Zonally averaged January and July precipitation rates (convective, stable, and total) for the MAA experiment and the observationalestimatesof Legates and Willmatt [ 1990].

600 7OO 8OO

istics and the striking similarity to the MAA model climate in the mid- to upper-tropospheric structure. The low-level differencesare clearly attributableto the incorporationof an explicit atmospheric boundary layer parameterization, as shown by Haltslag and Boville [1993]. The upper level stability structure seems to be a signature of the moist adiabaticadjustmentprocedureand appearsto have little to do with the vertical resolutionemployedby the model. Figure 12 illustrates the July temperature and moisture

9OO 1000 320

Figure 11. Zonally and meridianally (14.5øN to 14.5øS) averaged July equivalent potential temperature for the NCAR CCM2, the MAA experiment, and the ECMWF analyses (July 1988-1991). Results from the NCAR CCM1 are also included

for reference.

HACK:

PARAMETERIZATION

OF MOIST

CONVECTION

5561

du•y

o

,

,

,

i

,

i ,, , ,,,• ,

!

'-' ' '•

lOO

,

,

,

!

,

,

,

!

,

,

July

o

,

Yap I,land 9.4' N, 138.1' r

•

.

,

.

,

..

: :.• [

' ' '•

lOO

200

.

.

.

.

,

.

.

.

•

.

.

.

M•en.lon I.Iond 7.6' S, 14.2' W

200

,.• 300

,• 300

400

400

500

5oo

600

600

700

700

80O

800

go0

900

1000

1000

190

210

230

250

270

290

310-4

0

4

".%,. ß

0BS

,.

190

210

230

6T

Temperature(øK)

",.

250

270

290

310 -4

o

0

lOO

100

..

ß ,,,,,,!

"•,' '

ß , ,,,,,,i

, • ...... i

0

4

6T

Temperature (øK) , , ,,,,,,!

Asoen.lon I.land .6' S, 14.2' W

N, 138.1' E 200•'• ........ '......... ....... ......

200

,• 300

,.• 300

E 400

400

"•'\ x

L. 500

oK

u) 600

5oo

\'•

600 ß oK

•' 700

ß

700.....

800

800

gO0

900

lOOO

1000

10-s

10-2

10-I

100

10I

10-s

o

Specific Humidity(g/Kg)

q rofio

10-2

'

10-I

100

10•

Specific Humidity(g/Kg)

q ratio

Figure 12. Verticalprofilesof temperatureand specifichumidityat Yap IslandandAscensionIslandfor the NCAR CCM2 and the MAA experiment.Observedvaluesare givenby dotswhere the horizontalerror bars show the standard deviation of the observed interannual variability. The right-hand panels show

profilesof the differencein modeltemperaturebetweenthe NCAR CCM2 and the MAA experimentand profilesof the ratio of MAA specifichumidityto CCM2 specifichumidity. See text for further discussion. diffusion, dominated by boundary layer processes,and the net radiative heating. The contribution of these latter terms to the total diabatic forcing will be consideredlater when we examine each of these experiments on a regional basis. Although qualitatively similar there are some important differences between the two sets of figures. The first feature to note is the vertical extent and structure of both the heating and moistening in the vicinity of the ITCZ. The simulated ITCZ is well defined by both diabatic forcing terms, which reach clear secondary maxima in the middle tropospherefor

moistening that occurs near the trade inversion in the

subtropics. Thismoistening exceeds 0.5 g kg-• d-• in the CCM2 control but is completely absent in the MAA experiment. This detrainment of water mass in the dry subsiding branch of the Hadley circulation is also associatedwith a coolingeffect, which is largely responsiblefor the improved meridional

definition

of the ITCZ.

The CCM2

results also

cally integrated tendencies. We note that even though the CCM2 employs considerablyhigher vertical resolution, the

show some evidence of very weak cooling near the tropopause(i.e., at the top of the convective layer). This cooling is due to the flux divergence of liquid water static energy, which slightly dominates the convective-scalerainwater sink term in this region. The cooling occurring in the lower troposphericpolar region is associatedwith a large low-level convective overturning in a fairly dry atmosphere where, once again, the liquid water static energy flux plays a dominant role. This convective overturning appears to be radiatively driven, i.e., by a very large cloud top cooling gradient in this region (e.g., where the maximum cooling

vertical

exceeds3øCd-] in the zonalmean).

the

CCM2

control.

This

is not the case for the MAA

experiment, which exhibits a rather weakly defined and meridionally diffuse forcing in the ITCZ. Another characteristic of the MAA experiment is that the amplitude of the low-level forcing is larger and more localized in the vertical than in the CCM2

distribution

results and tends to dominate

of latent

heat

release

the verti-

in the

MAA

experiment is remarkably similar to earlier versions of the CCM that employed the moist adiabatic adjustment scheme. Another very important difference in the two figuresis the

The January zonally averaged convective mass flux, M c, is shown in Figure 15, along with the January zonally averagedlarge-scalevertical motion field. Enhancedconvec-

5562

HACK:

PARAMETERIZATION

January

the CCM2

ConvectiveHeating (C/day)

o o o

*

60(

lOO(

80N

40N

0

OF MOIST

405

805

Latitude(degrees) January Convective Moistening

200•'''''''''''''''' .-_

:

o 400-

--

0

* 600-

800: 'iøu .. "'•

CONVECTION

and the MAA-CCM2

difference

are shown in

Figure 16. Note the large increase in low-level cloud in the deep tropics and the large vertical shift of low-level cloud cover poleward of 70øN. Recall that there was a very large difference in the zonally averaged thermal structure in this region (see Figure 7), suggestingthat the temperature change is likely attributable to changesin the cloud-radiative balance introduced by the change in the convection scheme (i.e., the moist adiabatic adjustment schemecontributesto a downward shift of polar cloud cover and an accompanying vertical shift in the location of the thermal inversion). In the tropics the increase in low cloud cover is related to a significant increase in low-level relative humidity for the MAA experiment and suggestsan increase in stable condensation at these levels. This is indeed the case, as we will now show by examining the breakdown of the terms contributing to the diabatic heating shown in Figures 13 and 14. There are three components to the CCM2 "convective" heatingand moisteningrates shownin Figure 13, while there are only two for the MAA experiment (see Figure 14). The CCM2 components consist of the vertical eddy flux divergence terms (i.e., the convective-scale transport terms), the convective-scale condensate term (i.e., condensate removed from the systemin the form of convective precipitation), and

---

January

--

ConvectiveHeating (C/day)

--

1000 "; , , 80N

40N

0

405

805

Latitude(degrees) Figure 13. (a) Zonally averaged January convective heating rate and (b) zonally averagedconvectivemoisteningrate for the NCAR CCM2. Contour intervals are 0.25, 0.5, 1.0,

o o o

1.5, 2.0,... øC d-], and 0.25, 0.5, 1.0, 1.5, 2.0,... g kg-] d-•, respectively. Shaded areasin Figure13bdenote areas of convective moisteningin the descendingbranch of the mean meridional

circulation.

80N

tive activity is well correlated with the ascendinglarge-scale vertical motion in the ITCZ, exhibitingmassexchangethat is 2 to 3 times the large-scale value. Vigorous convective activity occurs throughout the lower troposphere, even in regions of intense subsidence.The midlatitude storm tracks can be identified by low to midlevel enhancementsin convection, and the intense low-level convective overturning poleward of 70øN can be clearly seen. One of the interestingquestionstheseexperimentsraise is what role the variousphysicalprocessesplay in maintaining the climatological balance establishedin each of the model experiments.The first hint that there are significantlydifferent roles for some of the physicscomponentscomesfrom an examination of the predicted cloud field. The global mean cloudinessincreasesby about2.4% in the MAA experiment, a statistically and physically significant change (e.g., the radiativeimpactis comparableto a CO2 doubling).The most interesting aspect of this change is its distribution in the vertical where the global high-level cloud cover actually decreases by about 2%, global midlevel cloud increases between 1% and 2%, and globallow-level cloudincreasesby almost 10%. The zonally averagedJanuarycloudfraction for

40N

0

405

805

Latifude(degrees) January Convective Moistening

80N

40N

0

40S

80S

Latitude(degrees) Figure 14. (a) Zonally averaged January convective heating rate and (b) zonally averagedconvective moisteningrate for the MAA experiment. Contour intervals are 0.25, 0.5,

1.0, 1.5,2.0,... øCd-•,and0.25,0.5, 1.0, 1.5,2.0,... g kg-• d- • respectively.

HACK:

PARAMETERIZATION

a stable condensate term (i.e., grid-scale condensate removed from the system in the form of precipitation). The MAA experiment explicitly includes only the latter two mechanisms, although there is an implied convective-scale vertical transport of total water as a by-product of the moist adiabatic adjustment procedure (where this effect is contained in the convective-scale condensation term). For example, the procedure maintains a constant relative humidity in the layers undergoing adjustment. Since the column is warmed by latent heat release, this process effectively transports water in the vertical to maintain a prespecified fraction

of the

behavior

later when we examine

saturation

value.

We

will

illustrate

OF MOIST

CONVECTION

January Cloud Fraction

- I I [ i I i i .-.::•]

•'800

,ooo ...... '""" '-'--'

this

80N

40N

0;ii:.....

::?!?ii

80S

January

•'-

•'

"'

o

..-..-•..-.:!•:;iiiii!11• ......... •.-.

"

800 . 80N

•::::::::::::.: ß ....... ::::!:•:!:!:!::.-

40S

[ACloud]

40N

0

405

805

Latitude (degrees)

January Vertical Velocity

200--

0

Latitude (degrees)

regional basis. For now, we focus on the zonally averaged diabatic heating as presented in Figures 13 and 14. The January CCM2 zonally averaged convective-scale heating tendency attributable to the vertical eddy flux of liquid water static energy is shown in the top panel of Figure 17. The eddy transport term exhibits a very distinct signature with strong, meridionally broad, heating confinedbelow 800 mbar and weaker cooling above. The heating maximum occurs near the top of the atmospheric boundary layer (i.e.,

around 900mbar),exceeding 2.5øCd-• at lowlatitudes. This

I

I ] [

*6oo: :ii ?"

each of the schemes on a

result is conceptually consistentwith previous budget studies showingthat moist convection (in particular, nonprecipitating moist convection) produces a cooling in the upper regions of the convective layer through the transport and

5563

:::::::::::::::::::::::

-

Figure 16. (a) Zonally averagedJanuary cloud fraction for the NCAR CCM2 and (b) the zonally averaged difference in January cloud fraction for the MAA experiment. Contour intervals are 0.025 (with shading greater than 0.15) and 0.05 (with shaded areas less than zero), respectively.

600-I

8002

detrainment of liquid water and a warming below [e.g., Betts, 1975]. The convective-scale condensationheating rate term, shown in the bottom panel of Figure 17, has considerably more meridional structure where the midlatitude storm tracks and ITCZ are clearly defined. Heating in the ITCZ

i.

•ooo

80N

40N

0

405

805

Latitude (degrees)

exceeds3.5øCd-] in the middletroposphere with much January

ConvectiveMass Flux (rnb/day)

õ 800 1000

• -

80N

--'........ '"•" ....... 40N

0

:•- • 40S

80S

Latitude (degrees) •igure IS. (a) Zona]ly averaged •anuary vc•ical motion field (•) in units of millibars per day and (b) the zonally

averaged •anuary convective mass flux, •, millibars per day for the NCAR CCM2.

in units of

smaller magnitudesin middle and high latitudes. Clearly, the eddy transport term plays an important role in the overall diabatic heating rate, in fact, the dominant role below 800 mbar. Since the total convective heating rates shown in Figures 13 and 14 are fairly similar in the lower troposphere, and an explicit convective-scale transport mechanism is not available to the moist adiabatic adjustment procedure, the low-level heating in the MAA experiment must be provided by either the convective-scale or stable condensation process. As it turns out, the stable condensation processprovides the bulk of the MAA low-level heating, as shown in the lower panel of Figure 18. Thus a substantial fraction

of the total latent heat release in the column

occurs

below 800 mbar in the MAA experiment, most all of which arisesfrom grid-scalecondensation.In sharp contrast, stable condensationis generally confined to the upper troposphere in the CCM2 control and represents a small fraction of the total latent heat released in the column

at low latitudes.

Once

again, the vertical partitioning of the total convective heating

5564

HACK:

PARAMETERIZATION

OF MOIST

CONVECTION

notation introduced by Yanai et al. [1973]. For the purpose of the following discussion,

January

EddyHeating(C/day)

g

0

L

L (28)

Q• = -- -- Fs + -- • + -- •s + QABL+ Q•,

CpOp

•

Q2 =

Cp

Cp

g

Cp

Fq •pp +l

• - •s + ,•

ABL ß

(29)

where fits is the rainwater sink for the stable condensation processand Q^BL and b•^BL are sourceterms attributableto atmospheric boundary layer (ABL) processes. The compart-

mentalization of O] and Q2 is purely for the purpose of identifying the relative role of the many functionally distinct component processesincluded in the numerical model and does not amount

January

CondensationHeating (C/day) I

i

[

[

I

'

•

'

I

[

i

]

I

•

[

i

I

200- -

tempted in budget studies of the real atmosphere, which does not concern itself with such discrete modeling abstractions. Vertical profiles of Q• and Q2 are shownin Figure 19 for both the CCM2 and the MAA experiments. The first

_

o 400-.

0

-

* 600Z •.

of the standard nomencla-

g/Cp(OFs/OP)AB L. Thesedistinctions are not typicallyat-

-

0

to a redefinition

ture. For example, the boundary layer contribution to the diabatic heating can also be thought of as a subcloudcomponent of the total vertical eddy transport such as Q^BL =

.

800: .

--

January

--

1000

80N

40N

0

40S

Large-scale Heating (C/day)

80S

Latitude(degrees) Figure 17. (a) Zonally averaged January diabatic heating by the convective-scale transport term and (b) by the convective-scale

rainwater

sink for the NCAR

intervalsare 0.25,0.5, 1.0, 1.5, 2.0,.-.

CCM2.

Contour

øCd-• wherethe

shaded region denotes cooling.

in the MAA model climate bears striking resemblance to earlier versions of the CCM. This suggeststhat the way in which the total heating is partitioned may be a general characteristic of the moist adiabatic adjustment procedure. That is, in the absence of an explicit vertical eddy heat transport term, other available physical processes must somehow heat the lower troposphere and do so by removing water from the system. This may be the principal reason why the MAA model climate is so dry when compared to the

80N

40N

0

40S

80S

Latitude (degrees) January

Large-scale Heating (C/day)

200• [[[I [[[I [[' I [••It --

CCM2

control.

¸ 400Z o

Regional Analysis of Total Diabatic Forcing

Let us now examine the behavior of the diabatic forcing in the CCM2 and MAA experiments on a regional basis. For this analysis we have selected a 500-km square region in the western Pacific in the vicinity of Truk Island during the month of July. This is a convectively active region in both experiments, typified by very similar large-scale vertical motion fields that peak between 400 mbar and 500 mbar. The maximum amplitude of the ascendingvertical motion field is about 75 mbar d -1 in the CCM2 control and 45 mbar d -1 in the MAA experiment. Our analysis will make use of the apparent heat source, Q1, and apparent moisture sink, Q2,

o

:

ß

600 Z 8001000

80N

40N

0

40S

80S

Latitude(degrees) Figure 18. Zonally averaged January diabatic heating by stable condensation for the (a) CCM2 and (b) MAA model climates. Contour intervals are 0.25, 0.5, 1.0, 1.5, 2.0,...

øC d -1 '

HACK:

PARAMETERIZATION

OF MOIST

thing to note is that the vertical structure of these profiles is really quite similar in the two experiments, although the magnitudes are moderately reduced for the MAA case. This weaker diabatic response is entirely consistent with the weaker large-scale adiabatic destabilization exhibited by the MAA experiment. The magnitudeand structureof the CCM2 Q• profile is in reasonable agreement with diagnostic budget studies conducted in this region [e.g., Yanai et al., 1973]. A breakdown of the apparentheat sourcecomponentsshowsthat the total diabatic heating is dominated by the convective-scale rainwater sink (see Figure 20). The remaining terms are of comparable magnitude but exhibit distinctly different structures in the vertical. Generally speaking,above 800 mbar the convective-scale and grid-scale water sinks strongly heat the atmosphere, while the radiation and convective transport terms contribute comparably to a cooling. Note that the stable condensationprocess is a significantheating component only in the upper troposphere between 200 mbar and 500 mbar. Below 800 mbar the moist convective transport term acts to strongly heat the atmosphere, while boundary layer processesheat below 900 mbar and cool above. A number of the apparent heat sourcecomponentsfor the MAA experiment are qualitatively similar to the CCM2 results. dominant

The

convective-scale

term and exhibits

rainwater a similar

sink

vertical

remains

structure.

CONVECTION

5565

July Western Pacific 0

•,•,

c'cfi2':

loo

i

•

,

i

,

i

,

i

,

i

C4mveu--•ve Conden•fe

,

"., ----- EddyTran.port :• _•_.:• .... Radiation

200 -

ABL

/,? i/I t

$00

400 500

I;

600 700 800 900 1000

-4

-3

-2

-1

0

1

2

5

4

5

6

'C/day

July Western Pacific o

k,,. ----- Eddy Tran.po

lOO

• •s ..... Rodlotion

200

•/,o/'r\x• ---$loble Conden.ate

$oo

the 400

The

net radiational cooling is also qualitatively similar but exhibits a small peak in low levels attributable to enhancedcloud top cooling (due to the increase in low-level cloud, as discussed earlier). Although somewhat weaker, the ABL contribution is similar to the CCM2 results. The important differencesare the absenceof an eddy convective transport term, which heats below and cools above 800 mbar in the CCM2 results, and the presence of a large stable condensation heating below 800 mbar. Effectively, this grid-scale heating takes up the role of the missingeddy transport term below 800 mbar, as suggested by the zonally averaged results presented earlier.

I! 500

; ;

/

600

700 /'

800 900

1000

-4

-3

-2

-1

0

1

2

;5

....

4

5

'C/day

Figure 20. July area-averaged terms in the (a) CCM2 and (b) MAA Q • budgetsshownin Figure 19. See text for further discussion.

July Western Pacific

lOO

200 5oo

400 500

600

ß

/

700 800 900 1000

-•

-3

-2

-1

0

1

2

3

4

5

6

aC/doy

Figure 19. July area-averagedQ• (solid) and Q2 (dashed) profiles for the CCM2 (thick) and MAA (thin) model climates. The area average is taken over a 500-km square region in the vicinity of Truk Island in the western Pacific.

The vertical structure of the CCM2 Q2 profile does not agree with diagnostic budget estimates as well as the Q• structure, particularly below 800 mbar. A similar statement holds for the MAA results. The moisture forcing below 800 mbar changes sign, exhibiting a very large moisture source, as opposedto a moisture sink found in most budget analyses. A breakdown of the Q2 components(see Figure 21) shows that although the convective-scale water sink and stable condensation water sink dominate the budget above 800 mbar, boundary layer processesplay the major role in the moisture budget below 800 mbar. The very large moisture source attributable to the ABL scheme is not completely balanced by the convective-scale total water flux, resulting in the appearance of a large net moisture source below 800 mbar. The magnitude of the ABL moisture source is comparable in both the CCM2 and the MAA results (• 10øC

d-•), eventhoughit is consumed in verydifferentwaysby other physical processes. This strongly suggeststhat the ABL scheme is far too active with regard to moisture transport in low levels. We note that this excessive low-level mixing of water may also be a contributing factor to the weak upper level cold/dry anomaly present in the CCM2 model

5566

HACK:

PARAMETERIZATION

July Western Pacific

CONVECTION

Figure 7, these figures depict a model atmosphere that is systematically colder and dryer by as much as 3øC and 2 gm

o

kg-1 in thezonalaverage.Theresemblance of theseresults

lOO

to the MAA experiment is remarkable. The detailed mechanisms for achieving the climate balance in these two experiments are quite different, since the Arakawa and Mintz scheme has an extra degree of freedom available to it. They share a common attribute, however, which is the removal of water from the model atmosphere at low levels. This clearly illustrates the importance of transporting water in the vertical (subject to some minimum autoconversion) to deal with moist convective instability, as opposed to removing it entirely from the system.

200 5oo 400

500

600

700

800

..

-

lOOO

-8

OF MOIST

-6

-4

-2

o

2

4

6

5.

Concluding Remarks

We have presented the methodology by which the process of moist convection is parameterized in the NCAR CCM2. The scheme makes use of a bulk, three-level, stabilitydependent, nonentraining cloud model to constrain the adjustment to a stable stratification. The procedure also provides the framework for estimating the convective-scale mass exchange in general. We believe that this approach

øC/day

July Western Pacific 0

100 200 500

Janua•

400

[AT]

500

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ß

2oo

700

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