# Analytical solutions for nonlinear plasma waves with time-varying   complex frequency

**Authors:** Benjamin J. Q. Woods

arXiv: 1905.03104 · 2019-10-22

## TL;DR

This paper develops analytical methods to study the evolution of nonlinear plasma waves with time-varying complex frequencies, extending classical BGK solutions to include frequency sweeping modes and their nonlinear dynamics.

## Contribution

It introduces a formalism for analyzing plasma waves with time-dependent complex frequencies using Taylor expansions and basis decompositions, providing new analytical solutions and insights.

## Key findings

- Derived solutions for time-varying complex frequencies in plasma waves.
- Presented approximate solutions for constant f contours in nonlinear regimes.
- Identified highly nonlinear orbits with larger velocity widths than BGK islands.

## Abstract

Bernstein-Kruskal-Greene (or BGK) modes are ubiquitous nonlinear solutions for the 1D electrostatic Vlasov equation, with the particle distribution function $f$ given as a function of the particle energy. Here, we consider other solutions $f = f[\epsilon]$ where the particle energy is equal to the second-order velocity space Taylor expansion of the function $\epsilon(x,v,t)$ near the wave-particle resonance. This formalism allows us to analytically examine the time evolution of plasma waves with time-varying complex frequency $\omega(t) + i \gamma(t)$ in the linear and nonlinear phases. Using a Laplace-like decomposition of the electric potential, we give allowed solutions for the time-varying complex frequencies. Then, we show that $f$ can be represented analytically via a family of basis decompositions in such a system. Using a Gaussian decomposition, we give approximate solutions for contours of constant $f$ for a single stationary frequency mode, and derive the evolution equation for the nonlinear growth of a frequency sweeping mode. For this family of modes, highly nonlinear orbits are found with the effective width in velocity of the island roughly a factor of $\sqrt{2}$ larger than the width of a BGK island.

## Full text

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## Figures

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## References

27 references — full list in the complete paper: https://tomesphere.com/paper/1905.03104/full.md

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Source: https://tomesphere.com/paper/1905.03104