Open AccessOvercoming the Boundary Layer Turbulence at Dome C: Ground-Layer Adaptive Optics versus Tower
Author(s) -
Tony Travouillon,
Laurent Jolissaint,
M. C. B. Ashley,
Jon Lawrence,
J. W. V. Storey
Publication year - 2009
Publication title -
publications of the astronomical society of the pacific
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.294
H-Index - 172
eISSN - 1538-3873
pISSN - 0004-6280
DOI - 10.1086/600077
Subject(s) - boundary layer , adaptive optics , telescope , turbulence , inversion (geology) , planetary boundary layer , dome (geology) , atmospheric turbulence , tower , geology , optics , meteorology , physics , remote sensing , mechanics , engineering , paleontology , civil engineering , structural basin
The unique atmospheric conditions present at sites such as Dome C on the Antarctic plateau are very favorable for high spatial resolution astronomy. At Dome C, the majority of the optical turbulence is confined to a 30 to 40 m thick stable boundary layer that results from the strong temperature inversion created by the heat exchange between the air and the ice-covered ground. To fully realize the potential of the exceptionally calm free atmosphere, this boundary layer must be overcome. In this article we compare the performance of two methods proposed to beat the boundary layer: mounting a telescope on a tower that physically puts it above the turbulent layer, and installing a telescope at ground level with a ground-layer adaptive optics system. A case is also made to combine these two methods to further improve the image quality.12 page(s
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