高温等离子体中的声波 III.双周期扰动

IF 2.7 3区 物理与天体物理 Q2 ASTRONOMY & ASTROPHYSICS
S. B. Derteev, M. E. Sapraliev, N. K. Shividov, B. B. Mikhalyaev
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引用次数: 0

摘要

这项工作的目的是研究日冕稀薄高温等离子体中声波的色散及其在传播该区域发生的强度扰动(PDs)中的作用。我们认为,在日冕洞和日冕环中观测强度扰动时记录到的小波频谱的多周期性是压缩波的弥散和阻尼共同作用的结果。观测结果表明,存在连续的频谱,其周期由适当的最大值区分。频谱的形状是局部扰动的特征。这项研究基于我们之前提出的高温等离子体中非绝热波的清晰模型,该模型考虑了热传导、辐射冷却和持续加热的特性。热传导形成了波群速度的局部最小值,将周期短和周期长的波群分开。第一组波具有强分散性和弱阻尼性,而第二组波则具有相反的特性。这种效应导致初始脉冲扰动最终获得一种形式,在这种形式中,所显示的波群被明显分开。小波频谱中出现了两个最大值,它们决定了短周期 \(P_{s}\)和长周期 \(P_{l}\)。具有优势周期的两组波以相同的速度传播,小于声速。我们假定,在低层大气小尺度扰动的影响下,日冕中确实会出现 PDs 形式。观测到的扰动速度也小于声速。这通常可以用投影效应来解释,但也可以用 PD 以群体速度传播这一事实来解释。通过观测 PD 在日冕中记录到的时间信号与几个谐波分量的叠加几乎没有什么相似之处。观测到的周期并不规则,在整个观测时间(通常为 2 - 3 小时)内可能会发生多次变化。我们建议将 PD 视为一系列独立的脉冲干扰。两个周期仅出现在一个给定的脉冲中,其持续时间为一个长周期 \(P_{l}\),通常为 20 - 30 分钟。它们可能在下一个脉冲中发生变化,因为它们取决于在日冕和低层大气边界形成的初始脉冲的长度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Acoustic Waves in a High-Temperature Plasma III. Two-Periodic Disturbances

The aim of this work is to study the dispersion of acoustic waves in the rarefied high-temperature plasma of the solar corona and its role in propagating intensity disturbances (PDs) occurring in this region. We believe that a multi-periodicity in wavelet spectra, recorded when observing PDs in coronal holes and loops, is due to a result of the combined effect of dispersion and damping of compression waves. Observations show the presence of continuous spectra, where periods are distinguished by suitable maxima. The shape of the spectra is characteristic of localized disturbances. This study is based on our previously proposed clear model of nonadiabatic waves in high-temperature plasma, which takes into account the properties of thermal conduction, radiative cooling, and constant heating. Thermal conduction forms a local minimum of group speed, separating groups of waves with short and long periods. Waves of the first group have strong dispersion and weak damping while waves of the second group have the opposite properties. This effect leads to the fact that the initial pulse disturbance eventually acquires a form in which the indicated groups are clearly separated. Two maxima appear in the wavelet spectrum which determine the short period \(P_{s}\) and the long period \(P_{l}\). Two groups of waves with dominant periods propagate at the same speed, which is less than the sound speed. We assume that the form of PDs can indeed arise in the corona under the influence of small-scale disturbances in the lower atmosphere. The speed of the observed disturbances is also less than the sound speed. This is usually explained by the projection effect, but can also be explained by the fact that PDs propagate with a group speed. The time signals in the corona recorded by observing PDs bear little resemblance to the superposition of just a few harmonic components. The observed periods are not regular, they can change several times during the entire observation time (often 2 – 3 hours). We propose to consider PDs as a sequence of independent pulse disturbances. Two periods occur only in a given pulse, the duration of which is on the order of a long period \(P_{l}\), often 20 – 30 minutes. They may change in the next pulse, since they depend on the length of the initial pulse formed at the boundary of the corona and the lower atmosphere.

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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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