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Wesley Berg, Tristan L’Ecuyer, and Sue van den HeeverWesley Berg, Tristan L’Ecuyer, and Sue van den Heever
Department of Atmospheric ScienceDepartment of Atmospheric ScienceColorado State UniversityColorado State University
Evaluating the impact of aerosols on the onset and microphysical properties of rainfall off the coast of China
Differences in TRMM Rainfall DetectionFebruary 1, 2000
Impact of Aerosols on Rainfall Detection?
TMI-PR Rain Detection Differences SPRINTARS Sulfate AOD
Calipso 532 nm Attenuated Backscatter
Aerosol Layer(~3-5 km)
Coincident TRMM/CloudSat Case3 April 2007
Coincident TRMM/CloudSat Case3 April 2007
Rain Rate Histograms3 April 2007
Differences in Radar SensitivityTRMM PR (13.8 GHz) vs. CloudSat (94 GHz)
Simulated Near-Surface ZCloud
Refl
ecti
vit
y (
dB
Z)
Drizzle Cloud
LWC (gm-3) Rainrate (mm h-1)
MDS = 18 dBZ
MDS = -28 dBZ
PR
CPR
1 6 10 15 0.1 1 10 100
Coincident TRMM/CloudSat Case3 April 2007
Cloud Resolving Model SimulationsCSU RAMS
3-D Cloud Structure Transect of Cloud Liquid Water
Cloud Resolving Model SimulationsEffect of Variations in Sulfate Aerosol Optical Depth
Cloud Water Path Rain Water Path
Total Water Path
Cloud Resolving Model SimulationsEffect of Variations in Sulfate Aerosol Optical Depth
Accumulated Precipitation
Ratio of Cloud Water Path to Total Water Path
Probability of Precipitation versus Liquid Water Path
Summary
• Differences in rain fraction between PR and TMI off the coast of China point to a modification of cloud microphysical properties by aerosols.
– Magnitude is substantial (i.e. the frequency of occurrence leads to large differences in the total rain (up to ~50% or 2 mm/day) locally.
• Results from 3 April 2007 Case and “Idealized” CRM Simulations– Consistency in rain area between TMI and CloudSat indicate the presence of large-
scale light rain and/or drizzle below the PR detection threshold (~17 dBZ)
– High AOD CRM simulation has substantially more cloud water and the onset of rain is delayed.
– This is consistent with the observations as higher cloud water paths may lead to an overestimate of the rain rate by TMI/CloudSat and possible underestimate by the PR as a result of smaller drops initially. In addition, the delay in the development of rain drops may be a factor leading to the underestimate of the rain area by PR.
• Results from Statistical Analysis (Global ocean analysis from 2007)– Probability of precipitation decreases significantly in high sulfate aerosol environment.
– Aerosol effect is evident in both stable and unstable environments.
– Results are consistent using either SPRINTARS sulfate AOD or MODIS aerosol index.
Primary Objective: To provide, from space, the first global survey of cloud profiles and cloud physical properties, with seasonal and geographical variations needed to evaluate the way clouds are parameterized in global models, thereby contributing to weather predictions, climate and the cloud-climate feedback problem.
The CloudSat Mission
• Nadir pointing, 94 GHz radar
• 3.3s pulse 500m vertical res.• 1.4 km horizontal res.• Sensitivity ~ -28 dBZ• Dynamic Range: 80 dB• Antenna Diameter: 1.85 m• Mass: 250 kg• Power: 322 W
500m
~1.4 km
The Cloud Profiling Radar
TRMM SensorsPrecipitation radar (PR):
13.8 GHz
4.3 km footprint
0.25 km vertical res.
215 km swath
Microwave radiometer (TMI):
10.7, 19.3, 21.3, 37.0
85.5 GHz (dual polarized
except for 21.3 V-only)
10x7 km FOV at 37 GHz
760 km swath
Visible/infrared radiometer (VIRS):
0.63, 1.61, 3.75, 10.8, and 12 :
at 2.2 km resolution
Lightning Imaging Sensor (LIS )
Cloud & Earth Radiant Energy System (CERES)
Nov. 1997 launch, 35° inclination; 402 kmNov. 1997 launch, 35° inclination; 402 km
Tropical Rainfall Measuring Mission Tropical Rainfall Measuring Mission (TRMM)(TRMM)