Impact of the numerical conversion to optical depth on the transfer of polarized radiation

Matteo D'Anna, G. Janett, L. Belluzzi
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Abstract

Making the conversion from the geometrical spatial scale to the optical depth spatial scale is useful in obtaining numerical solutions for the radiative transfer equation. This is because it allows for the use of exponential integrators, while enforcing numerical stability. Such a conversion involves the integration of the total opacity of the medium along the considered ray path. This is usually approximated by applying a piecewise quadrature in each spatial cell of the discretized medium. However, a rigorous analysis of this numerical step is lacking. This work is aimed at clearly assessing the performance of different optical depth conversion schemes with respect to the solution of the radiative transfer problem for polarized radiation, out of the local thermodynamic equilibrium. We analyzed different optical depth conversion schemes and their combinations with common formal solvers, both in terms of the rate of convergence as a function of the number of spatial points and the accuracy of the emergent Stokes profiles. The analysis was performed in a 1D semi-empirical model of the solar atmosphere, both in the absence and in the presence of a magnetic field. We solved the transfer problem of polarized radiation in different settings: the continuum, the photospheric Sr i AA modeled under the assumption of complete frequency redistribution, and the chromospheric Ca i AA taking the partial frequency redistribution effects into account during the modeling. High-order conversion schemes generally outperform low-order methods when a sufficiently high number of spatial grid points is considered. In the synthesis of the emergent Stokes profiles, the convergence rate, as a function of the number of spatial points, is impacted by both the conversion scheme and formal solver. The use of low-order conversion schemes significantly reduces the accuracy of high-order formal solvers. In practical applications, the use of low-order optical depth conversion schemes introduces large numerical errors in the formal solution. To fully exploit high-order formal solvers and obtain accurate synthetic emergent Stokes profiles, it is necessary to use high-order optical depth conversion schemes.
光学深度的数值转换对偏振辐射传输的影响
将几何空间尺度转换为光学深度空间尺度有助于获得辐射传递方程的数值解。这种转换涉及沿所考虑的射线路径对介质的总不透明度进行积分,通常通过在离散介质的每个空间单元中应用分段正交来近似实现。然而,目前还缺乏对这一数值步骤的严格分析。这项工作旨在明确评估不同光学深度转换方案在解决偏振辐射辐射传递问题方面的性能,以及在局部热力学平衡状态下的性能。我们分析了不同的光学深度转换方案及其与普通形式求解器的组合,包括作为空间点数量函数的收敛速度和出现的斯托克斯剖面的精确度。我们在不同的环境中解决了偏振辐射的转移问题:连续体、在完全频率再分布假设下建模的光球层 Sr i AA,以及在建模过程中考虑了部分频率再分布效应的色球层 Ca i AA。在合成新出现的斯托克斯剖面时,收敛速度作为空间点数的函数,受到转换方案和形式求解器的影响。在实际应用中,使用低阶光学深度转换方案会在形式解中产生较大的数值误差。要充分利用高阶形式解算器并获得精确的合成新兴斯托克斯剖面,就必须使用高阶光学深度转换方案。
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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