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SIO209 Cloud Climate Feedbacks. Scripps Institution of Oceanography University of California. Dr. Piotr J. Flatau pcirrus@gmail.com. SIO209 Clouds. SIO209 Clouds. SIO209 Clouds. SIO209 Cloud Climate Feedbacks. Radiative Convective Equilibrium Feedbacks Cloud Physics Feedbacks
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SIO209 Cloud Climate Feedbacks Scripps Institution of Oceanography University of California Dr. Piotr J. Flatau pcirrus@gmail.com
SIO209 Clouds
SIO209 Clouds
SIO209 Clouds
SIO209 Cloud Climate Feedbacks • Radiative Convective Equilibrium Feedbacks • Cloud Physics Feedbacks • Cloud Formation Feedbacks
SIO209 Cloud Climate Feedbacks • Radiative Convective Equilibrium Feedbacks • Cloud Physics Feedbacks • Cloud Formation Feedbacks
SIO209 Radiative Convective Equilibrium - Examples Clear sky energy balance (IR cooling) Mid morning max. precipitation in tropics Observed temperature differences between fall and spring Stratocumulus balance (subsidence, heat flux, IR cooling) Convection control of SST in the tropics Lapse rate stabilization or destabilization
SIO209 Radiative Convective Equilibrium – IR cooling -100 W/m2 IR cooling RCE (“W. M. Gray”)
SIO209 Radiative Convective Equilibrium - Definition To first order, the atmosphere exists in a state of quasi balance between radiative cooling and the convective processes that give rise to latent and sensible heating.
SIO209 Radiative Convective Equilibrium - 1K/day Radiative cooling - clear sky dT/dt = - F/(cp rho Dz) =-100/(1004 *1.2* 8000) [K/s]= -100/(1000 * 8000) *(60*24*60)= 36*24 10^4/ 8*10^6=36*24/(800)=36*4/100 =about= 1.0K/day
SIO209 RCE - Up Moist Down Dry Evaporation Q=mL= 1g * 2.5 * 10^3J/g F=2.5* 10^3/(24*60*60)= 1/36 W/cm2=1000/3.6 W/m2=250W/m2 L=2.5*10^6 J/kg 1W=1J/s 0.3cm evaporation per day to offsets 100W/m2 of IR cooling
SIO209 RCE Example: Precipitation in Tropics
SIO209 Early Morning Precip Max in Tropics - RCE
Implications for deep convection Mapes, 2002 Hartmann & Larson, 2002
SIO209 Stratocumulus RCE
SIO209 Lilly’s Model of Sc. RCE d T /dt = - (Fnet,base-Fnet,top)/ (cp rho dz) Fnet,top=75W/m2 Fnet,base=15W/m2 Cp=1004 J kg^-1 K^-1 Rho=1.2 kg m^-3 Dz=1km dT/dt=-4 K/day (IR) Subsidence (30mb/d-100W/m2) Heat flux
SIO209 Radiative Convective Equilibrium – SST Control
SIO209 Radiative Convective Equilibrium – SST Control
SIO209 Radiative Convective Equilibrium – Thermostat
SIO209 Radiative Convective Equilibrium Adjustment
SIO209 Radiative Convective Equilibrium – Summary
