Conversion and Smoothing of MHD Shocks in Atmospheres with Open and Closed Magnetic Field and Neutral Points

Pennicott, Jamon D.; Cally, Paul S.

doi:10.48550/arxiv.2105.02329

Cited by 1 publication

(1 citation statement)

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“…In either case though, it splits into distinct acoustically-dominated (now slow) and magnetically dominated (now fast) components in the overlying low-𝛽 upper chromosphere. In the case of shocks, the resulting slow wave is smoothed and soon ★ E-mail: abbas.raboonik@monash.edu † E-mail: paul.cally@monash.edu re-shocks, but the fast wave remains a shock (Pennicott & Cally 2021). However, the fast wave in the upper chromosphere is strongly reflected by the steep Alfvén speed gradient, or the transition region if it reaches it, and so contributes little directly to the corona (Srivastava et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Benchmarking Hall-Induced Magnetoacoustic to Alfvén Mode Conversion in the Solar Chromosphere

Raboonik¹,

Cally²

2021

Preprint

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A 2.5D numerical model of magnetoacoustic-Alfvén linear mode conversions in the partially ionised low solar atmosphere induced by the Hall effect is surveyed, varying magnetic field strength and inclination, and wave frequency and horizontal wave number. It is found that only the magnetic component of wave energy is subject to Hall-mediated conversions to Alfvén wave-energy via a process of polarisation rotation. This strongly boosts direct mode conversion between slow magnetoacoustic and Alfvén waves in the quiet low chromosphere, even at mHz frequencies. However, fast waves there, which are predominantly acoustic in nature, are only subject to Hall-induced conversion via an indirect two-step process: (i) a geometry-induced fast-slow transformation near the Alfvén-acoustic equipartition height 𝑧 eq ; and (ii) Hall-rotation of the fast wave in 𝑧 > 𝑧 eq . Thus, for the two-stage process to yield upgoing Alfvén waves, 𝑧 eq must lie below or within the Hall-effective window 0 𝑧 700 km. Magnetic field strengths over 100 G are required to achieve this. Since the potency of this Hall effect varies inversely with the field strength but directly with the wave frequency, only frequencies above about 100 mHz are significantly affected by the two-stage process. Increasing magnetic field inclination 𝜃 generally strengthens the Hall convertibility, but the horizontal wavenumber 𝑘 𝑥 has little effect. The direct and indirect Hall mechanisms both have implications for the ability of MHD waves excited at the photosphere to reach the upper chromosphere, and by implication the corona.

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Section: Introductionmentioning

confidence: 99%