Waves in the lower solar atmosphere: the dawn of next-generation solar telescopes

Jess, D. B.; Jafarzadeh, Shahin; Keys, Peter H.; Stangalini, M.; Verth, G.; Grant, S. D. T.

doi:10.1007/s41116-022-00035-6

Cited by 28 publications

(15 citation statements)

References 713 publications

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“…As a result, we should focus on the results for the range ℓ < v A1 τ in order to avoid loss of accuracy of the model. We are able to specify how the pulse is driven via the boundary conditions; in Scalisi et al (2021a), we suggested that a pulse driven for around 150 s could reach a maximum vertical extent matching the height of spicules, and this is within the range of the average period of torsional Alfvén waves in MBPs (where our hypothetical wave driver is located) given by Jess et al (2023). So, for example, if τ = 150 s, along with an estimate of v A1 = 10 km s −1 , we could consider ℓ < 1500 km.…”

Section: Discussionmentioning

confidence: 99%

“…In this analytical model, beginning with the ideal MHD equations and following on from the method of Scalisi et al (2021a), we consider a magnetic flux tube that acts as a waveguide for an Alfvén wave pulse. In this context, the vertical background magnetic field is assumed to be strong enough that magnetic forces dominate throughout the tube and thus the plasma beta is much less than unity (Jess et al 2023). We therefore use the zero-beta approximation and neglect the plasma pressure in comparison with the magnetic forces.…”

Section: Modelmentioning

confidence: 99%

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Generation of Vertical Flows by Torsional Alfvén Pulses in Zero-beta Tubes with a Transitional Layer

Scalisi

Erdélyi

2023

ApJ

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Spicule activity in the chromosphere is modeled via the perturbation resulting from the propagation of an Alfvén wave pulse in a magnetic flux tube. Building on previous work, the model is augmented by the inclusion of a finite transitional layer in which the atmospheric density decreases exponentially. This additional complexity of the density stratification provides a more physical representation of the solar atmosphere and improves on the existing model. The wave pulse is introduced at the lower boundary of the flux tube and interacts with the transitional layer, also being partially reflected. The total mass flux induced by the pulse, and the proportion of this pulse that is transmitted through the layer, is calculated and examined in the context of spicules and the solar wind using an example solution. We find that the inclusion of the transitional layer results in more plasma flux being transferred into the upper solar atmosphere when compared with the case of a discontinuity. We examine how varying the parameters of this transitional layer affects the ratio of the flux above and below the layer.

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Section: Discussionmentioning

confidence: 99%

Section: Modelmentioning

confidence: 99%

Generation of Vertical Flows by Torsional Alfvén Pulses in Zero-beta Tubes with a Transitional Layer

Scalisi

Erdélyi

2023

ApJ

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“…Thus, the smaller the R, the stronger the viscosity. Since m has inverse relation with the radius R, the waves in the small scale flux tube can be more unstable and more easily excited due to the DI in photospheric regions (see, e.g., Section 3.4 in Jess et al 2023), contributing to the enhancement of the wave propagations into the upper atmosphere.…”

Section: Dispersion Curves With Shear Flow and Viscositymentioning

confidence: 99%

Dissipative Instability of Magnetohydrodynamic Sausage Waves in a Compressional Cylindrical Plasma: Effect of Flow Shear and Viscosity Shear

Yu 유

2023

ApJ

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The shear flow influences the stability of magnetohydrodynamic (MHD) waves. In the presence of a dissipation mechanism, flow shear may induce an MHD wave instability below the threshold of the Kelvin–Helmholtz instability, which is called dissipative instability. This phenomenon is also called negative energy wave instability because it is closely related to the backward wave, which has negative wave energy. Considering viscosity as a dissipation mechanism, we derive an analytical dispersion relation for the slow sausage modes in a straight cylinder with a discontinuous boundary. It is assumed that the steady flow is inside and dynamic and bulk viscosities are outside the circular flux tube under photospheric condition. When the two viscosities are weak, it is found that for the slow surface mode, the growth rate is proportional to the axial wavenumber and flow shear, consistent within the incompressible limit. For a slow body mode, the growth rate has a peak at a certain axial wavenumber, and its order of magnitude is similar to surface mode. The linear relationship between the growth rate and the dynamic viscosity established in the incompressible limit develops nonlinearly when the flow shear and/or the two viscosities are sufficiently strong.

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“…Torsional Alfvén waves were also detected in the photosphere of a pore based on the optical flow detection of angular rotation (Stangalini et al 2021). Some of the key insights into these transverse waves in the solar chromosphere are found in excellent reviews (e.g., Srivastava et al 2021;Jess et al 2023;Morton et al 2023).…”

Section: Introductionmentioning

confidence: 99%

Alfvén Wave Connection between the Chromosphere and the Corona of the Sun: An Analytical Study

Chae,

Lee

2023

ApJ

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Alfvén waves are closely relevant to the three outstanding problems in the solar corona: coronal heating, solar wind acceleration, and the fractionization of low first ionization potential (FIP) elements. There has been increasing observational evidence for the Alfvén waves, not only in the corona, but also in the chromosphere. Here we investigate the Alfvén wave connection between the chromosphere and the corona based on the analytical solution of Alfvén waves in a layer where Alfvén speed varies along magnetic field lines with a constant gradient. The wave transmission of the layer is determined by two parameters: the Alfvénic cutoff frequency and the dimensionless thickness of the layer. It is shown that the ponderomotive acceleration originating from Alfvén waves is always directed upward in the solar atmosphere with the peak occurring in the chromosphere-corona transition region in association with downward low-frequency waves. We also find that some velocity amplitudes observed in the chromosphere of quiet regions and all the velocity amplitudes observed in active regions fall short of the theoretical estimates obtained with the assumption that the Alfvén waves generated below the chromosphere transport upward the energy required for the corona. We suggest considering the possibility that the Alfvén waves responsible for the coronal heating and the FIP fractionization originate from above the chromosphere.

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Waves in the lower solar atmosphere: the dawn of next-generation solar telescopes

Cited by 28 publications

References 713 publications

Generation of Vertical Flows by Torsional Alfvén Pulses in Zero-beta Tubes with a Transitional Layer

Generation of Vertical Flows by Torsional Alfvén Pulses in Zero-beta Tubes with a Transitional Layer

Dissipative Instability of Magnetohydrodynamic Sausage Waves in a Compressional Cylindrical Plasma: Effect of Flow Shear and Viscosity Shear

Alfvén Wave Connection between the Chromosphere and the Corona of the Sun: An Analytical Study

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