热不平衡对日冕磁柱内磁流体动力模式的影响

IF 6.1 2区 物理与天体物理 Q1 ASTRONOMY & ASTROPHYSICS Astronomy & Astrophysics Pub Date : 2025-02-19 DOI:10.1051/0004-6361/202450731
S. M. Hejazi, T. Van Doorsselaere, M. Sadeghi, D. Y. Kolotkov, J. Hermans
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引用次数: 0

摘要

目标。研究表明,由于光薄辐射能量损失与加热能量增益之间的差异而引起的热不平衡破坏了太阳日冕等离子体的绝热特性,直接影响了慢磁声波的传播。然而,作为任意强度的色散因子,这种热不平衡在多大程度上影响了作为地震学工具的慢模的使用,并影响了磁等离子体通量管内的香肠和扭结谐波模,这些问题仍未得到解决。本文研究了太阳日冕等离子体在有限轴向磁场的圆柱结构中,热不平衡对磁流体动力波色散的影响。具体来说,它考察了热不平衡如何影响色散关系,其特征是与冷却和加热功能直接相关的两个不同的时间尺度。这项研究是理解这些波的非绝热效应的关键途径。分析探讨了由经典热不平衡引起的非绝热效应的影响,其中加热和冷却时间尺度在对应于每种磁流体动力学模式的一系列值上变化。在日冕条件下,计算了磁流体动力波在有限磁场条件下通过磁等离子体管的色散关系。我们的研究结果表明,热不平衡对快速香肠和扭结模式的影响,与之前对平板的研究一致,很小,但比以前认为的稍微明显。这种影响在长波长范围内较小,但在短波长范围内增加,从而导致更高的阻尼率。尽管色散关系中热不平衡项的复杂相互作用,即使在特征时间尺度定义的低频限制下,这种对快模的轻微影响也会发生。此外,观察到一个非常小的放大,表明长波长基本快速扭结模式的抑制阻尼状态。相比之下,慢磁声模态受热不平衡的影响显著,在较小的纵波数下,尖峰频率略微向较低的值移动。这种热不平衡可能解释了在太阳大气中缓慢磁声波传播中观察到的大量衰减。长波长限制导致一个解析表达式,准确地描述了由于不平衡导致的慢模式的频率变化,与数值和观测结果密切一致。
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The effect of thermal misbalance on magnetohydrodynamic modes in coronal magnetic cylinders
Aims. It is well demonstrated that thermal misbalance, arising from the discrepancy between optically thin radiative energy loss and heating energy gain, disrupts the adiabatic nature of solar corona plasmas, directly affecting the propagation of slow magnetoacoustic waves. However, the extent to which this thermal misbalance, acting as a dispersion factor of an arbitrary intensity, influences the use of slow modes as seismological tools and affects sausage and kink harmonic modes within a magnetic plasma flux tube, remains unresolved.Methods. This study investigates the dispersion of magnetohydrodynamic waves influenced by thermal misbalance in a cylindrical configuration with a finite axial magnetic field within solar coronal plasmas. Specifically, it examines how thermal misbalance, characterized by two distinct timescales directly linked to the cooling and heating functions, influences the dispersion relation. This investigation is a key approach for understanding non-adiabatic effects on the behaviour of these waves.Results. The analysis explores the impact of non-adiabatic effects due to classical thermal misbalance, where the heating and cooling timescales vary across a range of values corresponding to each magnetohydrodynamic mode. The dispersion relation for magnetohydrodynamic waves propagating through a magnetic plasma tube, aligned with a finite magnetic field, is calculated under coronal conditions in the linear regime.Conclusions. Our findings reveal that the effect of thermal misbalance on fast sausage and kink modes, consistent with previous studies on slabs, is small but slightly more pronounced than previously thought. The impact is smaller at long-wavelength limits but increases at shorter wavelengths, leading to higher damping rates. This minor effect on fast modes occurs despite the complex interaction of thermal misbalance terms within the dispersion relation, even at low-frequency limits defined by the characteristic timescales. Additionally, a very small amplification is observed, indicating a suppressed damping state for the long-wavelength fundamental fast kink mode. In contrast, slow magnetoacoustic modes are significantly affected by thermal misbalance, with the cusp frequency shifting slightly to lower values, which is significant for smaller longitudinal wavenumbers. This thermal misbalance likely accounts for the substantial attenuation observed in the propagation of slow magnetoacoustic waves within the solar atmosphere. The long-wavelength limit leads to an analytical expression that accurately describes the frequency shifts in slow modes due to misbalance, closely aligning with both numerical and observational results.
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来源期刊
Astronomy & Astrophysics
Astronomy & Astrophysics 地学天文-天文与天体物理
CiteScore
10.20
自引率
27.70%
发文量
2105
审稿时长
1-2 weeks
期刊介绍: Astronomy & Astrophysics is an international Journal that publishes papers on all aspects of astronomy and astrophysics (theoretical, observational, and instrumental) independently of the techniques used to obtain the results.
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