Surface radiation balance and weather conditions on a non-glaciated coastal area in the Antarctic region

Meteorological measurements were performed on the non-glaciated coastal area of the Ferraz Station, the Brazilian Antarctic Station, at King George Island. Near the Station there are different topographic attributes, such as sea, glacier and hill, in addition to the intermittent presence of snow. Th...

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Bibliographic Details
Published in:Polar Science
Format: Article in Journal/Newspaper
Language:English
Published: 2019
Subjects:
Online Access:https://nipr.repo.nii.ac.jp/?action=repository_uri&item_id=15625
http://id.nii.ac.jp/1291/00015520/
Description
Summary:Meteorological measurements were performed on the non-glaciated coastal area of the Ferraz Station, the Brazilian Antarctic Station, at King George Island. Near the Station there are different topographic attributes, such as sea, glacier and hill, in addition to the intermittent presence of snow. The local atmospheric characteristics depend on wind direction, which is related in small scale to the local features and in large scale to the synoptic systems acting over the region. Westerly winds were the most frequent, with relatively lower speed and higher temperature and humidity values compared to the also frequent easterly winds, related to the coolest and driest winds. The average monthly barometric pressure and wind speed were higher during winter, associated with the presence of high-pressure systems. The radiation balance, measured for the first time in Ferraz Station, evidenced the presence of clouds throughout the year, especially during summer months, associated with the frequent synoptic systems of the region. During nighttimes (daytimes) and in winter (summer) months, the surface lost (gained) energy mainly by net longwave (shortwave) radiation. Reflected shortwave radiation was higher during spring months because of the its relatively higher albedo values combined with the already increased magnitude of the incident shortwave radiation.