Trapping of Electrons in Large-Amplitude Electrostatic Fields Resulting from Beam-Plasma Interaction

Wakeren, J. H. A. van; Hopman, H. J.

doi:10.1103/physrevlett.28.295

Cited by 38 publications

(12 citation statements)

References 6 publications

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“…Murata and Doniach suggested that the fourthorder term of the Landau expansion of the free energy in terms of uniform magnetization contains the mode-mode coupling term. 28 Generally, the mode-mode coupling in the model referred to by the authors is temperature dependent due to thermal excitation of spin fluctuations, but the effective coupling constant is independent of T and q vector. The mode-mode coupling is invariable as described in terms of the coefficient of the fourth-order termF 10 .…”

Section: A Temperature Dependence Of Magnetic Susceptibility Inmentioning

confidence: 99%

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGa
Yang
¹
,
Chen
²
,
Ohta
³

et al. 2011
Phys. Rev. B

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Ni 3 Al 1−x Ga x alloys are investigated by the measurements of isothermal magnetization, temperature variations of susceptibilities, and specific heats. Ga doping depresses the ferromagnetic transition temperature (T C ) continuously below the critical point x = 0.34. Near the critical region (x ≈ 0.34), the quantum critical scaling behaviors manifest themselves as the initial susceptibility χ −1 (T ) ∝ T 4/3 , T 4/3 C ∝ (x − x c ), and specific heat divided by temperature as C/T ∝ lnT at low temperatures. Furthermore, a novel spin-fluctuation spectrum was discovered in the samples near the quantum critical point, confirming the quantum critical point in this system. The magnetic properties in this system are understood almost in terms of the self-consistent renormalization and Takahashi's theory of spin fluctuations.

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Section: A Temperature Dependence Of Magnetic Susceptibility Inmentioning

confidence: 99%

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGa
Yang
¹
,
Chen
²
,
Ohta
³

et al. 2011
Phys. Rev. B

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“…where k is the wave number of the initial wave, Vph is the phase velocity of initial wave, V 0 is the particles velocity, the particles are not trapped into the potential well (a detailed presentation of this topic can be found, for instance, in [9][10][11] …”

Section: Initial Equationsmentioning

confidence: 99%

Decay instability of ion-acoustic wave train (or soliton) and formation of the shock profile

Demchenko

Hussein

1973

Z. Physik

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The stability of a periodic ion-acoustic wave of a finite amplitude propagating in a nonisothermal plasma is investigated. It is demonstrated that such a wave is unstable with respect to the splitting into a large number of satellite waves with effective wave numbers different from the wave number of the initial wave. The phase velocity of the satellite waves differs therefore from that of the initial pulse. Hence, the satellite waves with bigger phase velocity will "overtake" the initial pulse and turbulize the upstream plasma. The scattering of ions and electrons by the fluctuations of electric field of turbulent oscillations will cause the energy dissipation of the initial ionacoustic wave translational motion and produce a collisionless shock wave.

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“…[1][2][3][4][5][6][7] However, the physics is largely unexplored when a bounded supercritical plasma (x p > x) interacts with an external electromagnetic wave which itself is responsible for the genesis of the plasma. [8][9][10][11][12] The wave usually passes through the medium only when it is in the subcritical regime (x p < x).…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] Wakeren et al studied the trapping of beam electrons in potential well of electrostatic waves resulting from beam-plasma interaction. 1 Franklin et al investigated interaction of plasma electrons trapped in large amplitude electrostatic waves. 2 In another work, Danielson et al investigated oscillations with standing plasma waves in a trapped pure electron plasma.…”

Section: Introductionmentioning

confidence: 99%

Trapping of electrons in troughs of self generated electromagnetic standing waves in a bounded plasma column

et al. 2014

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Observations and measurements are reported on electron trapping in troughs of self-generated electromagnetic standing waves in a bounded plasma column confined in a minimum-B field. The boundaries are smaller than the free space wavelength of the waves. Earlier work of researchers primarily focused upon electron localization effects induced by purely electrostatic perturbation. We demonstrate the possibility in the presence of electromagnetic standing waves generated in the bounded plasma column. The electron trapping is verified with electrostatic measurements of the plasma floating potential, electromagnetic measurements of the wave field profile, and optical intensity measurements of Argon ionic line at 488 nm. The experimental results show a reasonably good agreement with predictions of a Monte Carlo simulation code that takes into account all kinematical and dynamical effects in the plasma in the presence of bounded waves and external fields. V C 2014 AIP Publishing LLC. [http://dx.

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Trapping of Electrons in Large-Amplitude Electrostatic Fields Resulting from Beam-Plasma Interaction

Cited by 38 publications

References 6 publications

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGa
Yang
¹
,
Chen
²
,
Ohta
³

et al. 2011
Phys. Rev. B

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGa
Yang
¹
,
Chen
²
,
Ohta
³

et al. 2011
Phys. Rev. B

Decay instability of ion-acoustic wave train (or soliton) and formation of the shock profile

Trapping of electrons in troughs of self generated electromagnetic standing waves in a bounded plasma column

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Trapping of Electrons in Large-Amplitude Electrostatic Fields Resulting from Beam-Plasma Interaction

Cited by 38 publications

References 6 publications

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGaYang1, Chen2, Ohta3 et al. 2011Phys. Rev. B

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGaYang1, Chen2, Ohta3 et al. 2011Phys. Rev. B

Decay instability of ion-acoustic wave train (or soliton) and formation of the shock profile

Trapping of electrons in troughs of self generated electromagnetic standing waves in a bounded plasma column

Contact Info

Product

Resources

About

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGa
Yang
¹
,
Chen
²
,
Ohta
³

et al. 2011
Phys. Rev. B

Spin fluctuations on the verge of a ferromagnetic quantum phase transition in Ni3Al1−xGa
Yang
¹
,
Chen
²
,
Ohta
³

et al. 2011
Phys. Rev. B