Abstract
Abstract. Satellite-based cloud base and top height (CBH and CTH) and cloud geometrical thickness (CGT) are validated against ground-based lidar
measurements and provide new scientific insights. The satellite measurements
are done by the Cloud-Aerosol Lidar and Infrared Pathfinder Satellite
Observation (CALIPSO). The retrieval methodology is built on the 333 m
resolution low-level water cloud data obtained from the Vertical Feature
Mask product of CALIPSO. The methodology is based on the definition that CBH
of boundary layer clouds is the lowest cloud base over an area of several
tens of kilometers. This allows taking the CBH of the neighboring penetrable
shallower cloud as having CBH representative for the entire cloud field. The
methodology over the ocean was validated based on observations from two
surface-based ceilometer measurements in the islands of Barbados and the
Azores, with an error standard deviation of ±115 m. Validation over
land was based on 4 years data of 138 terrestrial ceilometer sites with an
error standard deviation of ±220 m. The unprecedented accurate CBH
allows us to obtain CGT, which is an essential parameter in the
understanding of the aerosol–cloud interaction. Based on this newly
developed methodology, we retrieved the annual, seasonal, and diurnal
distributions of global CBH, CTH, and CGT for two years and analyzed the
variations of CBH and CTH over the ocean and land. Climatology of the annual
mean cloud geometrical properties shows the following. (1) The lowest CBH occurs over
the eastern margins of the subtropical oceans and increases westward from
300–400 to 800–900 m. The CGT increases from 300 to 1200 m, respectively. In
the western part of the tropical oceans, CBH is 500–600 m and CGT is
∼ 1500 m. (2) A narrow band of lower CBH and CGT occurs over
the Equator, especially over the eastern parts of the oceans. (3) CBH and
CGT over the tropical rain forests (Amazon and Congo) are 1200 and 1500 m,
respectively. CBH over the drier tropical land is 1500–2000 m, with CGT of 800–1000 m.
(4) CBH decreases towards Antarctica in the Southern Ocean, while CGT deepens. (5) Seasonally, the mid-latitude global oceans have the lowest CBH (mostly below 500 m) and CGT in summer seasons and the highest values in winter. (6) There is just an obvious difference between day and night for the maximum CTH and CGT over the tropics. Over the ocean, there is no discernible difference in CBH, but during night CTH is higher by ∼ 300 m.
Funder
National Natural Science Foundation of China
National Key Research and Development Program of China
Fundamental Research Funds for the Central Universities
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