Mesoscale Optical Turbulence simulations at Dome C

TL;DR

This study evaluates the Meso-Nh mesoscale model's ability to simulate optical turbulence and meteorological parameters at Dome C, Antarctica, aiming to improve site assessment for astronomy through 3D Cn2 mapping.

Contribution

First application of a mesoscale model to estimate optical turbulence profiles above Dome C, Antarctica, enhancing site evaluation methods for astronomy.

Findings

Meso-Nh accurately reproduces surface layer thickness Hsl.

Model successfully estimates optical turbulence in free atmosphere.

First mesoscale simulation of optical turbulence above Antarctic Plateau.

Abstract

These last years ground-based astronomy has been looking towards Antarctica, especially its summits and the internal continental plateau where the optical turbulence (OT) appears to be confined in a shallow layer close to the surface. Preliminary measurements have so far indicated pretty good value for the seeing above 30-35 m: 0.36" (Agabi et al. 2006), 0.27" (Lawrence et al. 2004) and 0.3" (Trinquet et al. 2008) at Dome C. Site testing campaigns are however extremely expensive, instruments provide only local measurements and atmospheric modeling might represent a step ahead towards the search and selection of astronomical sites thanks to the possibility to reconstruct 3D Cn2 maps over a surface of several kilometers. The Antarctic Plateau represents therefore an important benchmark test to evaluate the possibility to discriminate sites on the same plateau. Our group (Hagelin et al. 2008) has proven that the analyses from the ECMWF global model do not describe with the required accuracy the antarctic boundary and surface layers in the plateau. A better description could be obtained with a mesoscale model. The Meso-Nh model has proven to be reliable in reproducing 3D maps of OT above mid-latitude astronomical sites (Masciadri et al. 1999ab, 2004, Masciadri and Jabouille 2005). In this paper we study the ability of the Meso-Nh model in reconstructing the meteorological parameters as well as the OT above Dome C with different model configurations. We concentrate our attention on the model abilities in reproducing the OT surface layer thickness Hsl and the integral of the Cn2 in the free atmosphere and in the surface layer. It is worth to highlight that these are the first estimates ever done so far with a mesoscale model of the optical turbulence above the internal Antarctic Plateau.