Atmospheric dispersion correction: model requirements and impact on radial velocity measurements

Fourth International Conference on Applications of Optics and Photonics Pub Date : 2019-10-03 DOI:10.1117/12.2527256

B. Wehbe, A. Cabral, P. Figueira, G. Ávila

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Abstract

Observations with ground-based telescopes are affected by differential atmospheric dispersion when seen at a zenith angle different from zero, a consequence of the wavelength-dependent index of refraction of the atmosphere. One of the pioneering technology in detecting exoplanets is the technique of radial velocity (RV), that can be affected by uncorrected atmospheric dispersion. The current highest precision spectrographs are expected to deliver a precision of 10 cm/s (e.g., ESPRESSO). To minimize the atmospheric dispersion effect, an Atmospheric Dispersion Corrector (ADC) can be employed. ADC designs are based on sky dispersion models that nonetheless give different results; these can reach a few tens of milli-arcseconds (mas) in the sky (a difference up to 40 mas); a value close to the current requirements (20 mas in the case of ESPRESSO). In this paper we describe tests done with ESPRESSO and HARPS to understand the influence of atmospheric dispersion and its correction on RV precision. We also present a comparison of different sky models, using EFOSC2 data (between 600nm and 700nm), that will be used to improve on the design of ADCs.

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大气色散校正:模式要求和对径向速度测量的影响

地面望远镜的观测结果受到大气色散差异的影响，当观测的天顶角不同于零时，这是大气折射率随波长变化的结果。探测系外行星的前沿技术之一是径向速度(RV)技术，它可能受到未校正的大气色散的影响。目前精度最高的光谱仪预计可提供10厘米/秒的精度(例如，ESPRESSO)。为了最小化大气色散效应，可以使用大气色散校正器(ADC)。ADC的设计是基于天空色散模型的，但会给出不同的结果;这些在天空中可以达到几十毫弧秒(mas)(差异高达40 mas);一个接近当前要求的值(在ESPRESSO的情况下为20 mas)。本文介绍了利用ESPRESSO和HARPS进行的试验，以了解大气色散及其校正对RV精度的影响。我们还使用EFOSC2数据(在600nm和700nm之间)对不同的天空模型进行了比较，这将用于改进adc的设计。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Fourth International Conference on Applications of Optics and Photonics

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