# Effect of the Temperature of Background Plasma and the Energy of   Energetic Electrons on Z-Mode Excitation

**Authors:** Chuanyang Li, Yao Chen, Xiangliang Kong, M. Hosseinpour, Bing Wang

arXiv: 1906.01218 · 2019-07-31

## TL;DR

This study investigates how background plasma temperature and energetic electron energy influence Z-mode wave growth, frequency, and propagation angle, providing detailed parameter insights relevant to solar radio burst phenomena.

## Contribution

It offers a comprehensive parameter study on the effects of plasma temperature and electron energy on Z-mode instability, including wave frequency and propagation angle variations.

## Key findings

- Maximum growth rate decreases with increasing electron energy.
- Wave frequency exhibits step-wise jumps with parameter changes.
- Propagation angle varies with wave frequency and resonance conditions.

## Abstract

It has been suggested that the Z-mode instability driven by energetic electrons with a loss-cone type velocity distribution is one candidate process behind the continuum and zebra pattern of solar type-IV radio bursts. Both the temperature of background plasma ($T_0$) and the energy of energetic electrons ($v_e$) are considered to be important to the variation of the maximum growth rate ($\gamma_{max}$). Here we present a detailed parameter study on the effect of $T_0$ and $v_e$, within a regime of the frequency ratio ($10 \leq \frac{\omega_{pe}}{\Omega_{ce}} \leq 30$). In addition to $\gamma_{max}$, we also analyze the effect on the corresponding wave frequency ($\omega^r_{max}$) and propagation angle ($\theta_{max}$). We find that (1) $\gamma_{max}$ in-general decreases with increasing $v_e$, while its variation with $T_0$ is more complex depending on the exact value of $v_e$; (2) with increasing $T_0$ and $v_e$, $\omega^r_{max}$ presents step-wise profiles with jumps separated by gradual or very-weak variations, and due to the warm-plasma effect on the wave dispersion relation $\omega^r_{max}$ can vary within the hybrid band (the harmonic band containing the upper hybrid frequency) and the band higher; (3) the propagation is either perpendicular or quasi-perpendicular, and $\theta_{max}$ presents variations in line with those of $\omega^r_{max}$, as constrained by the resonance condition. We also examine the profiles of $\gamma_{max}$ with $\frac{\omega_{pe}}{\Omega_{ce}}$ for different combinations of $T_0$ and $v_e$ to clarify some earlier calculations which show inconsistent results.

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/1906.01218/full.md

## References

36 references — full list in the complete paper: https://tomesphere.com/paper/1906.01218/full.md

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Source: https://tomesphere.com/paper/1906.01218