Evalua&ng Downdra/ Parameteriza&ons with High Resolu&on CRM Data

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Evalua&ng Downdra/ Parameteriza&ons with High Resolu&on CRM Data Kate Thayer-Calder and Dave Randall Colorado State University October 24, 2012 NOAA's 37th Climate Diagnostics and Prediction Workshop

Convective Downdrafts Diagram: http://www.britannica.com/thunderstorms_tornadoes/ Cloudy air that flows downward after loading by precipitation or cooling by evaporation. Cooled air in the boundary layer creates cold pools and gust fronts.

Photo: http://wxbrad.com/downbursts-or-straight-line-winds-vs-tornadoes/ Photo: http://www.indianasnewscenter.com/news/local/wind- Turbines-Damaged-in-Ohio-148816585.html Diagram: http://www.srh.noaa.gov/jetstream/tstorms/wind.htm Downbursts and Microbursts (why you should care)

Gust Fronts (why you should care)

For the climate... Important source of cool air and moisture at low levels. Regulating influence on deep convection through reduction of CAPE. Organization of convection at gust front. Increased surface fluxes from cool, gusty winds Transport of clean mid-trophospheric air into the boundary layer.

Problems in GCMs Related to Downdrafts Deep convection occurs too frequently Moisture Anomalies Dry biases in the mid troposphere Deep convection is decoupled from the boundary layer Poor representation of tropical variability Issues with the ITCZ, monsoons, the diurnal cycle, MCSs, and others Figure: Kim et al. (2009)

Diagram: Arakawa and Schubert (1974)! Arakawa and Schubert (1974) : plume-based with no mention of downdrafts. Moorthi and Suarez (1992) : Relaxed AS, commonly used today, no downdrafts. Pan and Randall (1998) : No explicit downdrafts (CKE could be arguable) Park and Bretherton (2009) : The CAM5 shallow scheme, no downdrafts. How are downdrafts represented in GCMs? Missing in some

Diagram: Johnson (1976) Johnson (1976) : no mixing up/downdrafts, Md is a fixed fraction of Mu, Zd is a set fraction of updraft height Zhang and McFarlane (1995) : no mixing, Md is a fixed fraction of Mu, Zd is at min h*, evaporation limited to 20% of rain, all downdraft detrainment below cloud base Emanuel (1991) : Only environmental air entrained, fixed amount of precip available to evaporate How are downdrafts represented in GCMs? Radical simplifications.

How realistic are all of those assumptions? Photo: me

Testing Method Method: Use high resolution Cloud Resolving Model (CRM) runs to examine the effects of downdrafts. Model: System for Atmospheric Modeling (SAM) v6.8.2 Anelastic equations Prognostic liquid water/ice static energy, total non-precipitating water, and total precipitating water Single moment microphysics, CAM radiation, and parameterized sub-gridscale turbulence TOGA COARE Simulation 128x128 km 2 domain with 1km horizontal resolution 64 vertical levels up to 5hPa (About 100m resolution near the surface) 10 second timestep, ocean surface

Updrafts Environment Downdrafts Total Mass Flux (kg/s) Assumption: Downdrafts don t matter Downdrafts move as much or more mass vertically through the column as the dry environment does.

Assumption: Downdrafts only cool 299K layer - 12.5 days of TOGA

Assumption: Downdrafts only cool Variability created by coldpools increases the organization and propagation of convection through boundary layer convergence.

CAPE Assumption: Downdrafts only cool MSE CAPE variability created by coldpools can impart more buoyant properties to lifted parcels than the mean.

Assumption: Updrafts have mean BL Properties Updrafts are anomalously warm, and downdrafts are too. Negative buoyancy comes from condensate loading.

Updrafts Mean Assumption: Updrafts have mean BL Properties Cells marked as updrafts have a much higher CAPE than a parcel lifted with mean properties would.

How Realistic Are These Assumptions? Downdrafts are an important part of the vertical mass budget and should be included if only for this. Boundary layer variability created by downdraft coldpools enhances horizontal mass convergence and can force environmental lifting. Coldpools influence the initial thermodynamic properties of cloud parcels, and updrafts are more buoyant than assumed.

Improving the coupling between convection and the BL Improving the ability to forecast extreme weather is important, but... Climate models need work before they can reliably forecast tropical precipitation variability. TO DO: Ensure all climate models represent some form of downdraft mass flux Add a coldpool parameterization that represents parcel warming, surface flux changes, and mesoscale organization