Atmospheric Chemistry and Physics
www.atmos-chem-phys.net
1680-7316
1680-7324
10
13
2010
10.5194/acp-10-6255-2010
http://www.atmos-chem-phys.net/10/6255/2010/
http://www.atmos-chem-phys.net/10/6255/2010/acp-10-6255-2010.html
http://www.atmos-chem-phys.net/10/6255/2010/acp-10-6255-2010.pdf
6255
6269
2010-07-09
Microphysical variability in southeast Pacific Stratocumulus clouds: synoptic conditions and radiative response
D. Painemal
dpainemal@rsmas.miami.edu
P. Zuidema
Rosenstiel School of Marine and Atmospheric Sciences University of Miami, Florida, USA
Synoptic and satellite-derived cloud property variations for the southeast
Pacific stratocumulus region associated with changes in coastal
satellite-derived cloud droplet number concentrations (<i>N</i><sub><i>d</i></sub>) are explored.
MAX and MIN <i>N</i><sub><i>d</i></sub> composites are defined by the top and bottom terciles of
daily area-mean <i>N</i><sub><i>d</i></sub> values over the Arica Bight, the region with the
largest mean oceanic <i>N</i><sub><i>d</i></sub>, for the five October months of 2001, 2005,
2006, 2007 and 2008. The ability of the satellite retrievals to capture
composite differences is assessed with ship-based data. <i>N</i><sub><i>d</i></sub> and
ship-based accumulation mode aerosol concentrations (<i>N</i><sub><i>a</i></sub>) correlate well
(<i>r</i> = 0.65), with a best-fit aerosol activation value
<span style="border-bottom: 1px solid #000; vertical-align: 50%;
font-size: .7em; color: #000;"><i>d</i>ln <i>N</i><sub><i>d</i></sub></span><span style="margin-left: -2.7em;
margin-right: 0.5em; vertical-align: -45%; font-size: .7em; color: #000;"><i>d</i>ln <i>N</i><sub><i>a</i></sub></span>
of 0.56 for pixels with <i>N</i><sub><i>d</i></sub>>50 cm<sup>−3</sup>. The
adiabatically-derived MODIS cloud depths also correlate well with the
ship-based cloud depths (<i>r</i>=0.7), though are consistently higher (mean bias
of almost 60 m). The MAX-<i>N</i><sub>d</sub> composite is characterized by a weaker
subtropical anticyclone and weaker winds both at the surface and the lower
free troposphere than the MIN-<i>N</i><sub><i>d</i></sub> composite. The MAX-<i>N</i><sub>d</sub> composite
clouds over the Arica Bight are thinner than the MIN-<i>N</i><sub>d</sub> composite
clouds, have lower cloud tops, lower near-coastal cloud albedos, and occur
below warmer and drier free tropospheres (as deduced from radiosondes and
NCEP Reanalysis). CloudSat radar reflectivities indicate little near-coastal
precipitation. The co-occurrence of more boundary-layer aerosol/higher
<i>N</i><sub><i>d</i></sub> within a more stable atmosphere suggests a boundary layer source for
the aerosol, rather than the free troposphere.
<br><br>
The MAX-<i>N</i><sub><i>d</i></sub> composite cloud thinning extends offshore to 80° W, with
lower cloud top heights out to 95° W. At 85° W, the top-of-atmosphere
shortwave fluxes are significantly higher (~50%) for the
MAX-<i>N</i><sub>d</sub> composite, with thicker, lower clouds and higher cloud fractions
than for the MIN-<i>N</i><sub>d</sub> composite. The change in <i>N</i><sub><i>d</i></sub> at this location is
small (though positive), suggesting that the MAX-MIN <i>N</i><sub>d</sub> composite
differences in radiative properties primarily reflects synoptic changes.
Circulation anomalies and a one-point spatial correlation map reveal a
weakening of the 850 hPa southerly winds decreases the free tropospheric
cold temperature advection. The resulting increase in the static stability
along 85° W is highly correlated to the increased cloud fraction, despite
accompanying weaker free tropospheric subsidence.
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