Mesoscale optical turbulence simulations at Dome C

Lascaux, F.; Masciadri, E.; Hagelin, Susanna; Stoesz, J.

doi:10.1111/j.1365-2966.2009.15151.x

Cited by 33 publications

(53 citation statements)

References 21 publications

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“…The atmospheric models have been used for the first time to reconstruct and characterize the C 2 N profiles by Masciadri, Vernin & Bougeault (1999a,b). Since then, much progress has been achieved by our group: the model has been applied to different astronomical sites in a simple monomodel configuration (Masciadri, Vernin & Bougeault 2001; Masciadri & Garfias 2001) and more recently in a grid‐nesting configuration (Lascaux et al 2009), a new calibration technique has been proposed (Masciadri & Jabouille 2001) and statistically validated (Masciadri, Avila & Sanchez 2004) and the first application of the Meso‐Nh model as a tool of turbulence characterization has been presented (Masciadri & Egner 2006). However, so far we could always access GS measurements concentrated in a well‐defined period of time.…”

Section: Introductionmentioning

confidence: 99%

Optical turbulence vertical distribution with standard and high resolution at Mt Graham

Masciadri¹,

Stoesz²,

Hagelin³

et al. 2010

Monthly Notices of the Royal Astronomical Society

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A characterization of the optical turbulence vertical distribution (C2N profiles) and all the main integrated astroclimatic parameters derived from the C2N and the wind speed profiles above the site of the Large Binocular Telescope (LBT) (Mt Graham, Arizona, USA) is presented. The statistics include measurements related to 43 nights done with a Generalized SCIDAR (GS) used in standard configuration with a vertical resolution ΔH∼ 1 km on the whole 20 km and with the new technique (High Vertical Resolution GS) in the first kilometre. The latter achieves a resolution ΔH∼ 20–30 m in this region of the atmosphere. Measurements done in different periods of the year permit us to provide a seasonal variation analysis of the C2N. A discretized distribution of C2N, useful for the Ground Layer Adaptive Optics (GLAO) simulations, is provided and a specific analysis for the LBT Laser Guide Star system ARGOS (running in GLAO configuration) case is done including the calculation of the ‘grey zones’ for J, H and K bands. Mt Graham is confirmed to be an excellent site with median values of the seeing without dome contribution ɛ= 0.72 arcsec, the isoplanatic angle θ0= 2.5 arcsec and the wavefront coherence time τ0= 4.8 ms. We find that the OT vertical distribution decreases in a much sharper way than what has been believed so far in the proximity of the ground above astronomical sites. We find that 50 per cent of the whole turbulence develops in the first 80 ± 15 m from the ground. We finally prove that the error in the normalization of the scintillation that has been recently demonstrated in the principle of the GS technique affects these measurements by an absolutely negligible quantity (0.04 arcsec).

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Section: Introductionmentioning

confidence: 99%

Optical turbulence vertical distribution with standard and high resolution at Mt Graham

Masciadri¹,

Stoesz²,

Hagelin³

et al. 2010

Monthly Notices of the Royal Astronomical Society

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“…Studying the performance of the Antarctic Mesoscale Prediction System (described by Powers et al 2003) in retrieving surface temperature, Bromwich et al (2005) have shown that over the Antarctic plateau this model gives a positive bias of about 1 • C during the summer. Lascaux et al (2009), when comparing 47 radiosoundings temperature profiles collected at Dome C in the winter of 2005 with the results of a mesoscale model simulation, found substantial differences between experimental and model profiles in the first 200 m above the surface. Gallée and Gorodetskaya (2010) validated a limited area model over Dome C during the cold season.…”

Section: Introductionmentioning

confidence: 99%

“…For this reason, in recent years, the optical turbulence over the Antarctic plateau has been the subject of studies by astronomers (e.g. Aristidi et al 2005a,b;Geissler and Masciadri 2006;Hagelin et al 2008;Trinquet et al 2008;Lascaux et al 2009). As shown by e.g.…”

Section: Introductionmentioning

confidence: 99%

One Year of Surface-Based Temperature Inversions at Dome C, Antarctica

Pietroni

Argentini

Petenko

2013

Boundary-Layer Meteorol

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In 2005 the Study of Stable Boundary Layer Environment at Dome C (STA-BLEDC) experimental campaign was conducted at the plateau station of Concordia at Dome C, Antarctica. Temperature profiles measured with a microwave radiometer were used to study the characteristics of surface-based temperature inversions over the course of a year. Statistics of temperature profiles for every month are discussed; the difference between daytime and nocturnal cases observed during the summer months disappears during winter. Surface-based temperature inversions occurred in 70 % of the time during summer, and almost all of the time during winter. During winter the occurrence of warming events leads to a decrease in the temperature difference between the top and the base of the inversion (i.e. the inversion strength). The inversion strength maxima ranged between 3 • C (December) and 35 • C (August) corresponding to gradients of 0.1 and 0.3 • C m −1 , respectively. The average surface-based inversion height presents a daily cycle during the summer months with values up to 200 m in the morning hours, while it affects a layer always deeper than 100 m during the winter months. The relationships between inversion strength and the downward longwave radiative flux, absolute temperature, and wind speed are examined. The inversion strength decreases as the longwave radiation increases. A clear anti-correlation between inversion strength and near-surface temperature is evident throughout the year. During the winter, the largest inversion strength values were observed under low wind-speed conditions; in contrast, a clear dependence was not found during the summer.

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“…2006). More recently, it has been statistically validated above Dome C by Lascaux et al (2009Lascaux et al ( , 2010. The most important results obtained in these last papers are summarized in Table 1.…”

Section: Introductionmentioning

confidence: 87%

“…4 For this study, therefore, the RAMP Digital Elevation Model has been used. The orography of each area of interest in this study (Dome C, Dome A, South Pole) is displayed on Fig.…”

Section: Numerical Set-upmentioning

confidence: 99%

Optical turbulence: site selection above the internal Antarctic plateau with a mesoscale model

2010

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Atmospherical mesoscale models can offer unique potentialities to characterize and discriminate potential astronomical sites. Our team has recently completely validated the Meso-Nh model above Dome C . Using all the measurements of C 2 N profiles (15 nights) performed so far at Dome C during the winter time (Trinquet et al. 2008) we proved that the model can reconstruct, on rich statistical samples, reliable values of all the three most important parameters characterizing the turbulence features of an antarctic site: the surface layer thickness, the seeing in the free atmosphere and in the surface layer. Using the same Meso-Nh model configuration validated above Dome C, an extended study is now on-going for other sites above the antarctic plateau, more precisely South Pole and Dome A. In this contribution we present the most important results obtained in the model validation process and the results obtained in the comparison between different astronomical sites above the internal plateau. The Meso-Nh model confirms its ability in discriminating between different optical turbulence behaviors, and there is evidence that the three sites have different characteristics regarding the seeing and the surface layer thickness. We highlight that this study provides the first homogeneous estimate, done with comparable statistics, of the optical turbulence developed in the whole 20-22 km above the ground at Dome C, South Pole and Dome A.

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Mesoscale optical turbulence simulations at Dome C

Cited by 33 publications

References 21 publications

Optical turbulence vertical distribution with standard and high resolution at Mt Graham

Optical turbulence vertical distribution with standard and high resolution at Mt Graham

One Year of Surface-Based Temperature Inversions at Dome C, Antarctica

Optical turbulence: site selection above the internal Antarctic plateau with a mesoscale model

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