Convective Parameterization in Convective Parameterization in NWP ModelsNWP Models
Jack KainJack Kain
And And
Mike BaldwinMike Baldwin
What is convective What is convective parameterization?parameterization?
A technique used in NWP to predict the A technique used in NWP to predict the collective effects of (many) convective collective effects of (many) convective clouds that may exist within a single grid clouds that may exist within a single grid element…element…As a function of larger-scale As a function of larger-scale processes and/or conditions.processes and/or conditions.
Why do NWP models need to Why do NWP models need to worry about it?worry about it?
Direct Concern:Direct Concern: To Predict convective To Predict convective precipitationprecipitation
Feedback to larger Scales: Feedback to larger Scales: Deep convection Deep convection “overturns” the atmosphere, strongly affecting “overturns” the atmosphere, strongly affecting mesoscale dynamicsmesoscale dynamics- Changes vertical stability- Changes vertical stability- generates and redistributes heat- generates and redistributes heat- removes and redistributes moisture- removes and redistributes moisture- makes clouds, strongly affecting surface heating - makes clouds, strongly affecting surface heating and atmospheric radiationand atmospheric radiation
A convective parameterization A convective parameterization must decide 3 things:must decide 3 things:
• Activation? Trigger function
• Intensity? Closure Assumptions
• Vertical Distribution? Cloud model or specified profile
Trigger Functions
CAPECloudDepth
CIN
Moist.Conv.
Sub-cloudMass conv.
Cloud-layerMoisture ∂(CAPE)/∂t
BMJ(Eta)
Grell(RUC, AVN)
KF
(Research)
Bougeault(Meteo FR)
Tiedtke(ECMWF)
Bechtold(Research)
Emanuel(Research)
Closure Assumptions (Intensity)
CAPE Cloud-layermoisture
MoistureConverg.
∂(CAPE)/∂t SubcloudQuasi-equil.
BMJ(Eta)
Grell(RUC, AVN)
KF(Research)
Bougeault(Meteo FR)
Tiedtke(ECMWF)
Bechtold(Research)
Emanuel(Research)
Vertical Distribution of Heat, Moisture Entraining/Detraining
Plume
Convective Adjustment
Buoyancy SortingCloud Model
BMJ(Eta)
Grell(RUC, AVN)
KF(Research)
Bougeault(Meteo FR)
Tiedtke(ECMWF)
Bechtold(Research)
Emanuel(Research)
How is the parameterized How is the parameterized information fed back to the information fed back to the
model?model?
Consider the Temperature-Tendency Equation in a model:Consider the Temperature-Tendency Equation in a model:
sfcvmixhmixevapcondconvraddt
dPPPPPP /
Where the convective term is simply
c
initadj
convconv t
P
Consider two very different Consider two very different approaches:approaches:
1)1) BMJ Scheme (convective adjustment)BMJ Scheme (convective adjustment)
2)2) KF scheme (mass flux scheme)KF scheme (mass flux scheme)
Procedure followed by BMJ scheme…
1) Find the most unstable air in lowest ~ 200 mb
2) Draw a moist adiabat for this air
3) Compute a first-guess temperature-adjustment profile (Tref)
4) Compute a first-guess dewpoint-adjustment profile (qref)
The Next Step is an The Next Step is an EnthalpyEnthalpy AdjustmentAdjustment
First Law of Thermodynamics: vvp dqLdTCdH
With Parameterized Convection, each grid-point column is treated in isolation. Total column latent heating must be directly proportional to total column drying, or dH = 0.
dpqqLdpTTC vvref
P
P v
P
P refp
t
b
t
b
)(
Enthalpy is not conserved for first-guess profiles for this sounding!
Must shift Tref and qvref to the left…
Imposing Enthalpy Adjustment:Imposing Enthalpy Adjustment:
Adjusted Enthalpy Profiles:Adjusted Enthalpy Profiles:
Suppose the cloud layer was drier…reduce RH by 15%:Suppose the cloud layer was drier…reduce RH by 15%:
Enthalpy is conserved, but the net temperature Enthalpy is conserved, but the net temperature change is change is negativenegative, and the net moisture , and the net moisture
change is change is positivepositive: : Negative Precipitation!Negative Precipitation!
If we systematically change cloud-layer RH in this sounding, If we systematically change cloud-layer RH in this sounding, it can be shown that precipitation rate generated by the it can be shown that precipitation rate generated by the
scheme is very sensitive to deep-layer moisture:scheme is very sensitive to deep-layer moisture:
If the environment is too dry or CAPE layer is less If the environment is too dry or CAPE layer is less than ~ 200 mb deep, the scheme attempts to initiate than ~ 200 mb deep, the scheme attempts to initiate
shallow (non-precipitating) convectionshallow (non-precipitating) convection
1) Set cloud-top height as the level within 200 mb of LCL where RH falls off most rapidly with height.
2) Find LCL of cloud-top air; line connecting LCLs of subcloud and cloud-top air is a “mixing line”.
3) Assume Tref has same slope as mixing line; first-guess Tref is anchored on ambient temperature curve.
With Shallow Convection, there is no With Shallow Convection, there is no netnet temperature or moisture change:temperature or moisture change:
t
b
P
P refp dpTTC 0)( t
b
P
P vvrefv dpqqL 0)(and
Consider the impact of parameterized BMJ shallow Consider the impact of parameterized BMJ shallow convection in a “normal” diurnal cycle…convection in a “normal” diurnal cycle…
Model Initial Condition
Raob
BMX 12 Z 11 May 2000
Convective Adjustment Profiles…Convective Adjustment Profiles…
Initial time 1 h forecast
Convective Adjustment Profiles…Convective Adjustment Profiles…
3 h forecast
6 h forecast: BMJ convection inactive because “convective entropy change” would be negative. Sounding characteristics that lead to negative entropy change are not easily identified.
Other constraints that cause BMJ Other constraints that cause BMJ shallow convection to “abort”:shallow convection to “abort”:
- - qqrefref gives an increase in gives an increase in qq with height with height
- - qqrefref gives a negative gives a negative qq at some level at some level
- - TTrefref is super-adiabaticis super-adiabatic
- Net entropy change in cloud layer would be - Net entropy change in cloud layer would be negativenegative
- - TTrefref is isothermal is isothermal
- - qqrefref gives super-saturated gives super-saturated qq at some level at some level
Back to the convective Back to the convective adjustment profiles…adjustment profiles…
9 h forecast – 2100 UTC
Compare with raob at 00 Z: 12 h forecastCompare with raob at 00 Z: 12 h forecast
Model forecast
Raob
BMX 00Z 12 May 2000
Consider a transition from shallow to deep convection…Consider a transition from shallow to deep convection…
Model Initial Condition
Raob
FWD 00Z 20 April 2001
Convective Adjustment Profiles…Convective Adjustment Profiles…
1h Forecast
Compare with raob at 12 Z: 12 h forecastCompare with raob at 12 Z: 12 h forecast
Model forecast
Raob
FWD 12Z 20 April 2001
More Convective Adjustment Profiles…More Convective Adjustment Profiles…
16 h forecast 17 h forecast
Continuing to work on the sounding…Continuing to work on the sounding…
18 h forecast 21 h forecast
Compare with raob at 00 Z: 24 h forecastCompare with raob at 00 Z: 24 h forecast
Raob
Model Forecast
FWD 12Z 20 April 2001
BMJ Deep convection activated only briefly at FWD, but BMJ Deep convection activated only briefly at FWD, but 100 miles to the north (ADM), BMJ deep convection was 100 miles to the north (ADM), BMJ deep convection was
more persistent and strongly modified soundings:more persistent and strongly modified soundings:
EtaKF Model Forecast
Model Forecast
ADM 22 Z 20 April 2001
OK, consider the KF scheme, a “Mass-flux” OK, consider the KF scheme, a “Mass-flux” parameterizationparameterization
Basic procedures…Basic procedures…1) Starting at the surface, mix ~ 50 mb deep layers, lift to LCL2) Give parcel a boost based on low-level convergence. Can it reach the LFC?
3) If parcel makes it to LFC, allow it to rise and overshoot equilibrium level.
4) Form downdraft from air within ~ 200 mb of cloud base
5) Overturn mass in updraft, downdraft, and surrounding environment until stabilization is achieved.
If cloud depth 3 km, parameterize shallow convection
Updraft Source Layer
KF adjustment profilesKF adjustment profiles
Focus on deep convection…what is the Focus on deep convection…what is the Updraft Mass Flux (UMF*)?Updraft Mass Flux (UMF*)?
The mass of air that goes through cloud base divided by the initial mass in the ~ 50 mb updraft source layer:
UMF* = Mu/Musl
How is UMF How is UMF determined?determined?
What is UMF* sensitive to?What is UMF* sensitive to?
ee of downdraft air of downdraft air
Lapse rates in cloud layerLapse rates in cloud layer
Increasing humidity in the 900 – 550 mb layer increases downdraft e. This makes stabilization of the boundary layer less efficient and UMF* increases.
SummarySummary
Parameterized shallow convection can Parameterized shallow convection can distort sounding structures, significantly distort sounding structures, significantly affecting CIN and CAPE; more problematic affecting CIN and CAPE; more problematic with BMJ than with KFwith BMJ than with KF
BMJ deep convection very sensitive to BMJ deep convection very sensitive to cloud-layer RHcloud-layer RH
KF mass flux particularly sensitive to lapse KF mass flux particularly sensitive to lapse rates in lower half of cloud layer. rates in lower half of cloud layer.