Showing total 7 results

1. Energy principle for excitations in plasmas with counterstreaming electron flows.

Author

Kumar, Atul, Shukla, Chandrasekhar, Das, Amita, and Kaw, Predhiman

Subjects

*ELECTRON beams, *PLASMA gases, *ELECTROMAGNETIC fields

Abstract

A relativistic electron beam propagating through plasma induces a return electron current in the system. Such a system of interpenetrating forward and return electron current is susceptible to a host of instabilities. The physics of such instabilities underlies the conversion of the flow kinetic energy to the electromagnetic field energy. Keeping this in view, an energy principle analysis has been enunciated in this paper. Such analyses have been widely utilized earlier in the context of conducting fluids described by MHD model [I. B. Bernstein et al., Proceedings of the Royal Society of London A: Mathematical, Physical and Engineering Sciences 244(1236), 17–40 (1958)]. Lately, such an approach has been employed for the electrostatic two stream instability for the electron beam plasma system [C. N. Lashmore-Davies, Physics of Plasmas 14(9), 092101 (2007)]. In contrast, it has been shown here that even purely growing mode like Weibel/current filamentation instability for the electron beam plasma system is amenable to such a treatment. The treatment provides an understanding of the energetics associated with the growing mode. The growth rate expression has also been obtained from it. Furthermore, it has been conclusively demonstrated in this paper that for identical values of S 4 = ∑ α n 0 α v 0 α 2 / n 0 γ 0 α , the growth rate is higher when the counterstreaming beams are symmetric (i.e. S3 = ∑αn0α v 0α/n0γ0α = 0) compared to the case when the two beams are asymmetric (i.e. when S3 is finite). Here, v 0α, n0α and γ0α are the equilibrium velocity, electron density and the relativistic factor for the electron species ‘α’ respectively and n0 = ∑αn0α is the total electron density. Particle - In - Cell simulations have been employed to show that the saturated amplitude of the field energy is also higher in the symmetric case. [ABSTRACT FROM AUTHOR]

Published

2018

2. Terahertz Cherenkov radiation induced by a self-modulated electron beam in plasma wakefield.

Author

Yang, Shengpeng, Zhou, Qing, Tang, Changjian, Chen, Shaoyong, and Xia, Yuxi

Subjects

*CHERENKOV radiation, *ELECTRON beams, *PLASMA gases

Abstract

In this paper, a novel scheme of generating terahertz radiation is proposed, which considers a relativistic electron beam being modulated by its self-excited plasma wakefield in a plasma-filled slow-wave structure (SWS). Both the dispersion relation and the particle-in-cell simulation show that the self-modulation of the beam can act as a mode-selection method to excite the high-harmonics of the SWS and generate terahertz electromagnetic radiation. The present work gives a new thought for researching high-power and tunable terahertz sources. [ABSTRACT FROM AUTHOR]

Published

2019

3. The general dispersion relation of induced streaming instabilities in quantum outflow systems.

Author

Mehdian, H., Hajisharifi, K., and Hasanbeigi, A.

Subjects

*DISPERSION relations, *FILAMENTATION instability, *PLASMA gases

Abstract

In this manuscript the dispersion relations of streaming instabilities, by using the unique property (neutralized in charge and current by default) of plasma shells colliding, have been generalized and studied. This interesting property for interpenetrating beams enables one to find the general dispersion relations without any restrictions used in the previous works in this area. In our previous work [H. Mehdian et al., ApJ. 801, 89 (2015)], employing the plasma shell concept and boost frame method, the general dispersion relation for filamentation instability has been derived in the relativistic classical regime. But in this paper, using the above mentioned concepts, the general dispersion relations (for each of streaming instabilities, filamentation, twostream and multi-stream) in the non-relativistic quantum regime have been derived by employing the quantum fluid equations together with Maxwell equations. The derived dispersion relations enable to describe any arbitrary system of interacting two and three beams, justified neutralization condition, by choosing the inertial reference frame embedded on the one of the beams. Furthermore, by the numerical and analytical study of these dispersion relations, many new features of streaming instabilities (E.g. their cut-off wave numbers and growth rates) in terms of all involved parameters have been illustrated. The obtained results in this paper can be used to describe many astrophysical systems and laboratory astrophysics setting, such as collision of non-parallel plasma shells over a background plasma or the collision of three neutralized plasma slabs, and justifying the many plasma phenomena such as particle accelerations and induced fields. [ABSTRACT FROM AUTHOR]

Published

2015

4. Numerical study of the discharge properties of atmospheric dielectric barrier discharge by using 200 kHz/13.56 MHz excitations.

Author

Kong, F. R., Zhang, Z. L., and Jiang, B. H.

Subjects

*ELECTRIC discharges, *PLASMA gases, *ELECTRONS

Abstract

In this work involving an atmospheric dielectric barrier discharge system, the feasibility of independence control of key plasma parameters through strategic modulation of applied dual-frequency excitation sources is demonstrated. In this paper, a one-dimensional fluid model with semi-kinetic method has been used to investigate the discharge properties of atmospheric dielectric barrier discharge by using 200 kHz/13.56 MHz excitations. Bearing good consistency and coherence with experimental results, the electrical characteristics and typical electron dynamics are studied numerically. It is revealed that the application of the high frequency excitation can restrain the increment of the low frequency current component and is effective in preventing the discharge from transitioning to a filamentary mode. This method then suggests and enables possible approaches to obtain discharges with good stability in described DBD systems. [ABSTRACT FROM AUTHOR]

Published

2018

5. First investigation on plasma impurities of the IR-T1 tokamak.

Author

Alipour, R., Ghoranneviss, M., and Elahi, A. Salar

Subjects

*PLASMA gases, *INDUSTRIAL contamination, *EMISSION spectroscopy

Abstract

One of the best ways to get information about plasma and interactions within it, is the study on visible light emitted from plasma. Detection of the emission spectrum from plasma leads to identify the spectral lines of ions and impurities inside the plasma and measurement of all related parameters to ion flux such as velocity and temperature. The first measurement of impurities into the IR-T1 tokamak plasma is done by spectroscopic technique. The CCD-based spectrometer device with the wavelength range of 400-550 nm is used to detection the spectrum emitted from the plasma. The impurities into the plasma in the intended wavelength range are identified. Furthermore, the Doppler broadening of the most intense peaks of impurities and their temperatures are measured. The methods in this paper can be used on all fusion devices. [ABSTRACT FROM AUTHOR]

Published

2017

6. Synergistic catalytic removal NOX and the mechanism of plasma and hydrocarbon gas.

Author

Lei Zhang, Xiang-ling Sha, Hui-bin He, Long-wei Wang, Yu-xin Wang, and Li-xia She

Subjects

*HYDROCARBONS, *PLASMA gases, *DENITRIFICATION

Abstract

This paper using a method of catalytic adsorption combined with dielectric barrier discharge plasma which added to hydrocarbon gases. The different background gases, different dielectric properties and different pore sizes of the hydrolysis coke on the denitrification performance was studied. The effect of the coaction of plasma and the different properties of the removal of NO in flue gas was investigated, and the catalytic mechanism of the synergistic effect of plasma and hydrocarbon gas was discussed. The results shown that: The denitrification rate was significantly affected by plasma power and the initial concentration of NO; the reaction was restrained by the presence of oxygen and greatly promoted by the hydrocarbon gases. The permittivity of the catalyst has a great influence on the activity and the porous structure of the catalyst can obviously promote the reaction when the low temperature plasma combined with hydrocarbon gases. [ABSTRACT FROM AUTHOR]

Published

2016

7. Effect of nonlinear chirped Gaussian laser pulse on plasma wake field generation.

Author

Afhami, Saeedeh and Eslami, Esmaeil

Subjects

*LASER pulses, *GAUSSIAN beams, *PLASMA gases, *LASER beams, *ELECTRIC fields

Abstract

An ultrashort laser pulse propagating in plasma can excite a nonlinear plasma wake field which can accelerate charged particles up to GeV energies within a compact space compared to the conventional accelerator devices. In this paper, the effect of different kinds of nonlinear chirped Gaussian laser pulse on wake field generation is investigated. The numerical analysis of our results depicts that the excitation of plasma wave with large and highly amplitude can be accomplished by nonlinear chirped pulses. The maximum amplitude of excited wake in nonlinear chirped pulse is approximately three times more than that of linear chirped pulse. In order to achieve high wake field generation, chirp parameters and functions should be set to optimal values. [ABSTRACT FROM AUTHOR]

Published

2014