Kaixuan Yang, Tao Luo, Xuebin Li, Shengcheng Cui, Xiaoqing Wu, Kun Zhang
{"title":"Optical turbulence simulations over the Tibetan Plateau based on a single-column model with high-order closure.","authors":"Kaixuan Yang, Tao Luo, Xuebin Li, Shengcheng Cui, Xiaoqing Wu, Kun Zhang","doi":"10.1364/OE.539239","DOIUrl":null,"url":null,"abstract":"<p><p>Optical turbulence limits the maximum resolution of ground-based telescopes and leads to image degradation. The use of atmospheric numerical techniques to forecast optical turbulence is crucial for observation scheduling and optimization of adaptive optic systems. Current research methods for forecasting optical turbulence are primarily based on mesoscale models with turbulence closure techniques to parameterize the key terms required for <i>C</i> <i>n</i>2 calculations under the assumption of atmospheric quasi-steady-state balance, and then the integrated astroclimatic parameters related to <i>C</i> <i>n</i>2 profile can be obtained. In this study, we propose what we believe to be a novel approach to forecast <i>C</i> <i>n</i>2 using a boundary layer parameterization based on higher-order turbulence closure in the single-column framework of the CLUBB model. Compared to mesoscale models, the CLUBB model serves as a single-column model, which simplifies modifications and reduces compilation time, and is more conducive to testing the performance of <i>C</i> <i>n</i>2 parameterization scheme. In the design of <i>C</i> <i>n</i>2 parameterization scheme, we consider a more complete physical process rather than omitting certain terms to obtain a steady-state solution. The performance of the model is evaluated using measurements obtained during a field campaign conducted at Da Qaidam site above the Tibetan Plateau. The results show that the model is able to capture typical features of the <i>C</i> <i>n</i>2 profile evolution under convective conditions. Comparison of the model with contemporaneous sounding measurements and quantification of the model's performance using statistical operators demonstrate the statistical agreement between simulations and measurements. In terms of atmospheric seeing, we can observe a bias of 0.01 and a root-mean-square error (RMSE) of 0.31 without any model calibration, which outperforms the results of previous mesoscale modeling studies. In addition, the new parameterization scheme is also compared with two representative <i>C</i> <i>n</i>2 algorithms previously used in the mesoscale models, with some improvements observed. The potential demonstrated by this approach is expected to bring greater value and advancement to the research of three-dimensional forecasting of optical turbulence in the future by coupling with the mesoscale model.</p>","PeriodicalId":19691,"journal":{"name":"Optics express","volume":"32 23","pages":"40640-40665"},"PeriodicalIF":3.2000,"publicationDate":"2024-11-04","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Optics express","FirstCategoryId":"101","ListUrlMain":"https://doi.org/10.1364/OE.539239","RegionNum":2,"RegionCategory":"物理与天体物理","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"OPTICS","Score":null,"Total":0}
引用次数: 0
Abstract
Optical turbulence limits the maximum resolution of ground-based telescopes and leads to image degradation. The use of atmospheric numerical techniques to forecast optical turbulence is crucial for observation scheduling and optimization of adaptive optic systems. Current research methods for forecasting optical turbulence are primarily based on mesoscale models with turbulence closure techniques to parameterize the key terms required for Cn2 calculations under the assumption of atmospheric quasi-steady-state balance, and then the integrated astroclimatic parameters related to Cn2 profile can be obtained. In this study, we propose what we believe to be a novel approach to forecast Cn2 using a boundary layer parameterization based on higher-order turbulence closure in the single-column framework of the CLUBB model. Compared to mesoscale models, the CLUBB model serves as a single-column model, which simplifies modifications and reduces compilation time, and is more conducive to testing the performance of Cn2 parameterization scheme. In the design of Cn2 parameterization scheme, we consider a more complete physical process rather than omitting certain terms to obtain a steady-state solution. The performance of the model is evaluated using measurements obtained during a field campaign conducted at Da Qaidam site above the Tibetan Plateau. The results show that the model is able to capture typical features of the Cn2 profile evolution under convective conditions. Comparison of the model with contemporaneous sounding measurements and quantification of the model's performance using statistical operators demonstrate the statistical agreement between simulations and measurements. In terms of atmospheric seeing, we can observe a bias of 0.01 and a root-mean-square error (RMSE) of 0.31 without any model calibration, which outperforms the results of previous mesoscale modeling studies. In addition, the new parameterization scheme is also compared with two representative Cn2 algorithms previously used in the mesoscale models, with some improvements observed. The potential demonstrated by this approach is expected to bring greater value and advancement to the research of three-dimensional forecasting of optical turbulence in the future by coupling with the mesoscale model.
光学湍流限制了地面望远镜的最大分辨率,并导致图像质量下降。利用大气数值技术预报光学湍流对观测调度和自适应光学系统的优化至关重要。目前预报光学湍流的研究方法主要是基于中尺度模型,利用湍流闭合技术,在大气准稳态平衡的假设下,对 C n2 计算所需的关键项进行参数化,进而得到与 C n2 曲线相关的综合天文气候参数。在本研究中,我们提出了一种我们认为新颖的方法,即在 CLUBB 模式的单柱框架内,利用基于高阶湍流闭合的边界层参数化来预报 C n2。与中尺度模式相比,CLUBB模式作为单列模式,简化了修改,减少了编译时间,更有利于检验C n2参数化方案的性能。在设计 C n2 参数化方案时,我们考虑了更完整的物理过程,而不是省略某些项来获得稳态解。我们利用在青藏高原上的大柴旦地区进行的实地考察获得的数据对模型的性能进行了评估。结果表明,该模型能够捕捉对流条件下 C n2 剖面演变的典型特征。将模型与当时的探测测量结果进行比较,并使用统计算子对模型的性能进行量化,结果表明模拟结果与测量结果在统计上是一致的。在大气观测方面,我们可以观察到偏差为 0.01,均方根误差(RMSE)为 0.31,无需对模型进行任何校准,这优于之前的中尺度建模研究结果。此外,还将新的参数化方案与中尺度模式中以前使用的两种有代表性的 C n2 算法进行了比较,发现有一些改进。该方法所展示的潜力有望通过与中尺度模式的耦合,为未来光学湍流的三维预报研究带来更大的价值和进步。
期刊介绍:
Optics Express is the all-electronic, open access journal for optics providing rapid publication for peer-reviewed articles that emphasize scientific and technology innovations in all aspects of optics and photonics.