Amplification due to two-stream instability of self-electric and magnetic fields of an ion beam propagating in background plasma

Tokluoglu, Erinc; Kaganovich, Igor; Carlsson, Johan; Hara, Kentaro; Startsev, Edward A.

doi:10.1063/1.5038878

Cited by 11 publications

(11 citation statements)

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“…We focus on nonlinear stages of instability 200 ns after injection into a plasma, when we initialize time t = 0 presented in all figures. At t ≤ 0 ns, the potential mod- [30]. The potential in the plasma wave becomes very asymmetric and reaches about 1.6 kV at maximum at t = 8 ns.…”

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confidence: 99%

“…Note that a significant amount of electrons is accelerated and the position of the maximum of the VDF is shifted toward the negative velocity, so that the total current is maintained, i.e., the current of the ion beam pulse is fully neutralized by the plasma electrons in 1D case. This may be different in a multidimensional setup if the beam radius is small compared to the skin depth, because the elec- tron acceleration can occur along the beam axis and the return current may occur outside the beam [30].…”

mentioning

confidence: 99%

“…The ion beam propagates distance v b /τ B,i during the time τ B,i . Therefore, the strong defocusing forces caused by the two stream instability [19,30] can affect the ballistic beam propagation in plasmas only on distances shorter than v b /τ B,i .…”

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Generation of forerunner electron beam during interaction of ion beam pulse with plasma

2018

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The long-time evolution of the two-stream instability of a cold ion beam pulse propagating though the background plasma is investigated using a large-scale one-dimensional electrostatic kinetic simulation. The three stages of the instability are identified and investigated in detail. After the initial linear growth and saturation by the electron trapping, a portion of the initially trapped electrons becomes detrapped and moves ahead of the ion beam pulse forming a forerunner electron beam, which causes a secondary two-stream instability that preheats the upstream plasma electrons. Consequently, the self-consistent nonlinear-driven turbulent state is set up at the head of the ion beam pulse with the saturated plasma wave sustained by the influx of the cold electrons from the upstream of the beam that lasts until the final stage when the beam ions become trapped by the plasma wave. The beam ion trapping leads to the nonlinear heating of the beam ions that eventually extinguishes the instability.

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Generation of forerunner electron beam during interaction of ion beam pulse with plasma

2018

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“…Transport of a charged particle beam in a background plasma is the foundation for a variety of applications, such as inertial confinement fusion (Roth et al 2001;Logan, Perkins & Barnard 2008;Frolova, Khishchenko & Charakhch'yan 2019), high-energy particle accelerators and colliders (Govil et al 1999), radiography (Sheng et al 2014), astrophysics (Bennett 1934;Alfvén 1939;Spitkovsky 2007) and material etching (Lami et al 2020). Within the transport, the beam can strongly interact with background plasmas, potentially causing many physical phenomena, commonly including exciting periodic plasma wake-fields (Adli et al 2018;Caldwell et al 2018;Martinez de la Ossa, Mehrling & Osterhoff 2018;Turner et al 2019) and beam-plasma instabilities (Lee & Lampe 1973; Davidson et al 2004;Tokluoglu et al 2018). In addition, beam focusing may also be induced under some circumstances, which has aroused our great interest.…”

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confidence: 99%

The self-focusing condition of a charged particle beam in a resistive plasma

Ning

Liang

et al. 2021

J. Plasma Phys.

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The self-focusing condition of a charged particle beam in a resistive plasma has been studied. When plasma heating is weak, the beam focusing is intensified by increasing the beam density or velocity. However, when plasma heating is strong, the beam focusing is only determined by the beam velocity. Especially, in weak heating conditions, the beam trends to be focused into the centre as a whole, and in strong heating conditions, a double-peak structure with a hollow centre is predicted to appear. Furthermore, it is found that the beam radius has a significant effect on focusing distance: a larger the beam radius will result in a longer focusing distance. Simulation results also show that when the beam radius is large enough, filamentation of the beam appears. Our results will serve as a reference for relevant beam–plasma experiments and theoretical analyses, such as heavy ion fusion and ion-beam-driven high energy density physics.

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“…In the plasma bulk region, the ion streaming instability was predicted in many plasma environments, e.g. magnetized dusty plasmas (Rosenberg & Shukla 2004;Shukla et al 2008), auroral-acceleration-zone plasmas (Muschietti & Roth 2008), complex plasmas with non-Maxwellian ions (Kählert 2015;Quest, Rosenberg & Kercher 2017), negative ion source plasmas (Barminova & Chikhachev 2016;Kumar & Mathew 2017), electron-positron-ion plasmas (Saleem & Khan 2005) and ion beam propagation in inertial fusion plasmas (Tokluoglu et al 2018). In the plasma presheath region (i.e.…”

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confidence: 99%

Stability of different plasma sheaths near a dielectric wall with secondary electron emission

et al. 2019

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The linear theory stability of different collisionless plasma sheath structures, including the classic sheath, inverse sheath and space-charge limited (SCL) sheath, is investigated as a typical eigenvalue problem. The three background plasma sheaths formed between a Maxwellian plasma source and a dielectric wall with a fully self-consistent secondary electron emission condition are solved by recent developed 1D3V (one-dimensional space and three-dimensional velocities), steady-state, collisionless kinetic sheath model, within a wide range of Maxwellian plasma electron temperature $T_{e}$ . Then, the eigenvalue equations of sheath plasma fluctuations through the three sheaths are numerically solved, and the corresponding damping and growth rates $\unicode[STIX]{x1D6FE}$ are found: (i) under the classic sheath structure (i.e. $T_{e}<T_{ec}$ (the first threshold)), there are three damping solutions (i.e. $\unicode[STIX]{x1D6FE}_{1}$ , $\unicode[STIX]{x1D6FE}_{2}$ and $\unicode[STIX]{x1D6FE}_{3}$ , $0>\unicode[STIX]{x1D6FE}_{1}>\unicode[STIX]{x1D6FE}_{2}>\unicode[STIX]{x1D6FE}_{3}$ ) for most cases, but there is only one growth-rate solution $\unicode[STIX]{x1D6FE}$ when $T_{e}\rightarrow T_{ec}$ due to the inhomogeneity of sheath being very weak; (ii) under the inverse sheath structure, which arises when $T_{e}>T_{ec}$ , there are no background ions in the sheath so that the fluctuations are stable; (iii) under the SCL sheath conditions (i.e. $T_{e}\geqslant T_{e\text{SCL}}$ , the second threshold), the obvious ion streaming through the sheath region again emerges and the three damping solutions are again found.

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Amplification due to two-stream instability of self-electric and magnetic fields of an ion beam propagating in background plasma

Cited by 11 publications

References 53 publications

Generation of forerunner electron beam during interaction of ion beam pulse with plasma

Generation of forerunner electron beam during interaction of ion beam pulse with plasma

The self-focusing condition of a charged particle beam in a resistive plasma

Stability of different plasma sheaths near a dielectric wall with secondary electron emission

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