模拟日冕物质抛射及其驱动冲击对H i Ly $\alpha $线总强度的参数影响

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
Beili Ying, Guanglu Shi, Li Feng, Lei Lu, Jianchao Xue, Shuting Li, Weiqun Gan, Hui Li
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引用次数: 0

摘要

H i Ly\(α \)(121.6纳米)线形成机制与紫外线(UV)Ly\(α \)和白光(WL)观测相结合,为确定日冕物质抛射(CMEs)的电子温度提供了一种有效的方法。确保这一诊断技术准确性的关键是精确计算理论Ly\(α \)强度。本研究通过三维磁流体动力数值模拟,对CME及其驱动的冲击进行建模。然后,我们生成了几个太阳半径范围内的CME和冲击的合成紫外和可见光图像,以量化不同假设对理论Ly(α)强度的影响,如太阳色球Ly(α)线的入射强度(I_{disk}\)、几何散射函数(p(theta)),以及假定等于质子(T_{p})或电子(T_{e})温度的动力学温度(T_{boldsymbol{n}})。通过比较这些假设下CME和冲击的Ly(α)强度的差异,我们发现(1) 与同步图相比,使用盘面Ly(α)发射的均匀图或卡林顿图会低估日冕的Ly(α)强度(相对不确定性低于10%),除了在部分CME核心观察到的轻微高估(<4%)。卡林顿图的不确定性低于均匀盘。(2) 忽略几何散射过程对Ly(α)强度的影响相对较小,最大相对不确定性不超过5%。Ly\(α \)强度大部分被低估了,但在CME核心被高估了。(3) 与假设(T_{\boldsymbol{n}}=T_{p}\)相比,使用(T_{\boldsymbol{n}}=T_{e}\)会导致CME Ly\(α \)强度的相对不确定性更加复杂。CME的核心和空隙都被高估了,核心的最大相对不确定性超过了50%,而空隙则保持在35%以下。适当提高质子-电子温度比可以降低 CME 核心和空隙的不确定性。在 CME 前端,高估和低估都存在,相对不确定性低于 35%。电子温度假设对冲击的影响较小,低估的相对不确定性小于 20%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Parameter Effects on the Total Intensity of H i Ly\(\alpha \) Line for a Modeled Coronal Mass Ejection and Its Driven Shock

Parameter Effects on the Total Intensity of H i Ly\(\alpha \) Line for a Modeled Coronal Mass Ejection and Its Driven Shock

The combination of the H i Ly\(\alpha \) (121.6 nm) line formation mechanism with ultraviolet (UV) Ly\(\alpha \) and white-light (WL) observations provides an effective method for determining the electron temperature of coronal mass ejections (CMEs). A key to ensuring the accuracy of this diagnostic technique is the precise calculation of theoretical Ly\(\alpha \) intensities. This study performs a modeled CME and its driven shock via the three-dimensional numerical magneto-hydrodynamic simulation. Then, we generate synthetic UV and WL images of the CME and shock within a few solar radii to quantify the impact of different assumptions on the theoretical Ly\(\alpha \) intensities, such as the incident intensity of the solar chromospheric Ly\(\alpha \) line (\(I_{disk}\)), the geometric scattering function (\(p(\theta )\)), and the kinetic temperature (\(T_{ \boldsymbol{n}}\)) assumed to be equal to either the proton (\(T_{p}\)) or electron (\(T_{e}\)) temperature. By comparing differences of the Ly\(\alpha \) intensities of the CME and shock under these assumptions, we find that: (1) Using the uniform or Carrington maps of the disk Ly\(\alpha \) emission underestimates the corona Ly\(\alpha \) intensity (with relative uncertainties below 10%) compared to the synchronic map, except for a slight overestimate (<4%) observed in the partial CME core. The Carrington map yields lower uncertainties than the uniform disk. (2) Neglecting the geometric scattering process has a relatively minor impact on the Ly\(\alpha \) intensity, with a maximum relative uncertainty of no more than 5%. The Ly\(\alpha \) intensity is underestimated for the most part but overestimated in the CME core. (3) Compared to the assumption \(T_{\boldsymbol{n}}=T_{p}\), using \(T_{\boldsymbol{n}}=T_{e}\) leads to more complex relative uncertainties in CME Ly\(\alpha \) intensity. The CME core and void are both overestimated, with the maximum relative uncertainty in the core exceeding 50% and in the void remaining below 35%. An appropriate increasing proton-to-electron temperature ratio can reduce the uncertainty in the CME core and void. In the CME front, both overestimates and underestimates exist with relative uncertainties of less than 35%. The electron temperature assumption has a smaller impact on the shock, with an underestimated relative uncertainty of less than 20%.

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来源期刊
Solar Physics
Solar Physics 地学天文-天文与天体物理
CiteScore
5.10
自引率
17.90%
发文量
146
审稿时长
1 months
期刊介绍: Solar Physics was founded in 1967 and is the principal journal for the publication of the results of fundamental research on the Sun. The journal treats all aspects of solar physics, ranging from the internal structure of the Sun and its evolution to the outer corona and solar wind in interplanetary space. Papers on solar-terrestrial physics and on stellar research are also published when their results have a direct bearing on our understanding of the Sun.
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