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Your search keyword '"Angus, J. R."' showing total 29 results
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29 results on '"Angus, J. R."'

1. Simulation of FuZE axisymmetric stability using gyrokinetic and extended-MHD models

Author

Geyko, V. I., Angus, J. R., and Dorf, M. A.

Subjects
Physics - Plasma Physics
Abstract

Axisymmetric ($m=0$) gyrokinetic and extended-MHD simulations of sheared-flow Z-pinch plasma are performed with the high-order finite volume code COGENT. The present gyrokinetic model solves the long-wavelength limit of the gyrokinetic equation for both ion and electron species coupled to the electrostatic gyro-Poisson equation for the electrostatic potential. The electromagnetic MHD model includes the effects of the gyro-viscous pressure tensor, diamagnetic electron and ion heat fluxes, and generalized Ohm's law. A prominent feature of this work is that the radial profiles for the plasma density and temperature are taken from the FuZE experiment and the magnetic field profile is obtained as a solution of the MHD force balance equation. Such an approach allows to address realistic plasma parameters and provide insights into the current and planned experiments. In particular, it is demonstrated that the radial profiles play an important role in stabilization, as the embedded guiding center ($E{\times} B$) drift has a strong radial shear, which can contribute to the Z-pinch stabilization even in the absence of the fluid flow shear. The results of simulations for the FuZE plasma parameters show a decrease of the linear growth rate with an increase in the flow shear, however full stabilization in the linear regime is not observed even for large (comparable to the Alfv\'en velocity) radial variations of the axial flow. Nonlinear stability properties of the FuZE plasmas are also studied and it is found that profile broadening can have a pronounced stabilizing effect in the nonlinear regime.

Published
2020

2. Effect of insulator surface conditioning on the pinch dynamics and x-ray production of a Ne-filled dense plasma focus.

Author

Housley, D., Hahn, E. N., Narkis, J., Angus, J. R., Link, A. J., Conti, F., and Beg, F. N.

Subjects
PLASMA focus, DENSE plasmas, PLASMA sheaths, X-rays, PLASMA diagnostics, ELECTRIC breakdown, LASER plasmas
Abstract

The dense plasma focus (DPF) can be an intense source of x rays, wherein the insulator sleeve strongly dictates the electrical breakdown, which subsequently affects the formation of a plasma sheath and a collapse phase. Experiments on a 25 kJ DPF (operated at 4.4 kJ) are carried out to demonstrate the influence of insulator surface morphology on the pinch structure, dynamics, and x-ray yield using a Ne fill. Two borosilicate insulators are directly compared, one with a smooth finish and the other machined with four circumferential grooves traversing the perimeter of the exterior insulator surface. Comparisons are made through same-shot imaging diagnostics of the evolving plasma sheath during breakdown, rundown, and at the pinch in addition to the time-resolved measurements of emitted x rays via filtered photodiodes. The presence of structures on the insulator sleeve reduces x-ray production across all fill pressures by a factor of 2.8 ± 2.4 on average and reduces the highest x ray producing shots by a factor of 5.5 ± 1.8. Observations of sheath asymmetry and inhomogeneity at lift-off are observed and correlated with subsequent observations of off-axis radial collapse. Taken together, this suggests that local variations in the insulator surface decrease the spatial uniformity of the sheath, leading to an azimuthally asymmetric focus, reduced electron densities, and, ultimately, degraded x-ray production. [ABSTRACT FROM AUTHOR]

Published
2021
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24. Modeling nitrogen plasmas produced by intense electron beams.

Author

Angus, J. R., Mosher, D., Swanekamp, S. B., Ottinger, P. F., Schumer, J. W., and Hinshelwood, D. D.

Subjects
*NITROGEN, *NONMETALS, *PLASMA gases, *CATHODE rays, *ELECTRON beams, *ELECTRON bombardment conductivity
Abstract

A new gas-chemistry model is presented to treat the breakdown of a nitrogen gas with pressures on the order of 1 Torr from intense electron beams with current densities on the order of 10 kA/cm2 and pulse durations on the order of 100 ns. For these parameter regimes, the gas transitions from a weakly ionized molecular state to a strongly ionized atomic state on the time scale of the beam pulse. The model is coupled to a 0D-circuit model using the rigid-beam approximation that can be driven by specifying the time and spatial profiles of the beam pulse. Simulation results are in good agreement with experimental measurements of the line-integrated electron density from experiments done using the Gamble II generator at the Naval Research Laboratory. It is found that the species are mostly in the ground and metastable states during the atomic phase, but that ionization proceeds predominantly through thermal ionization of optically allowed states with excitation energies close to the ionization limit. [ABSTRACT FROM AUTHOR]

Published
2016
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27. Particle-in-cell simulations of electron beam control using an inductive current divider.

Author

Swanekamp, S. B., Angus, J. R., Cooperstein, G., Ottinger, P. F., Richardson, A. S., Schumer, J. W., and Weber, B. V.

Subjects
*ELECTRON beams, *ELECTRIC currents, *ELECTROMAGNETISM, *INDUCTIVE effect, *ROOT-mean-squares
Abstract

Kinetic, time-dependent, electromagnetic, particle-in-cell simulations of the inductive current divider are presented. The inductive current divider is a passive method for controlling the trajectory of an intense, hollow electron beam using a vacuum structure that inductively splits the beam's return current. The current divider concept was proposed and studied theoretically in a previous publication [Swanekamp et al., Phys. Plasmas 22, 023107 (2015)]. A central post carries a portion of the return current (I1), while the outer conductor carries the remainder (I2) with the injected beam current given by Ib=I1+I2. The simulations are in agreement with the theory which predicts that the total force on the beam trajectory is proportional to (I2-I1) and the force on the beam envelope is proportional to Ib. Independent control over both the current density and the beam angle at the target is possible by choosing the appropriate current-divider geometry. The root-mean-square (RMS) beam emittance (εRMS) varies as the beam propagates through the current divider to the target. For applications where control of the beam trajectory is desired and the current density at the target is similar to the current density at the entrance foil, there is a modest 20% increase in εRMS at the target. For other applications where the beam is pinched to a current density ~5 times larger at the target, eRMS is 2-3 times larger at the target. [ABSTRACT FROM AUTHOR]

Published
2015
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28. Electromagnetic drift waves dispersion for arbitrarily collisional plasmas.

Author

Wonjae Lee, Angus, J. R., and Krasheninnikov, Sergei I.

Subjects
*ELECTROMAGNETIC waves, *DISPERSION (Chemistry), *COLLISIONAL plasma, *PLASMA drift waves, *RESONANCE, *ION temperature
Abstract

The impacts of the electromagnetic effects on resistive and collisionless drift waves are studied. A local linear analysis on an electromagnetic drift-kinetic equation with Bhatnagar-Gross-Krook-like collision operator demonstrates that the model is valid for describing linear growth rates of drift wave instabilities in a wide range of plasma parameters showing convergence to reference models for limiting cases. The wave-particle interactions drive collisionless drift-Alfvén wave instability in low collisionality and high beta plasma regime. The Landau resonance effects not only excite collisionless drift wave modes but also suppress high frequency electron inertia modes observed from an electromagnetic fluid model in collisionless and low beta regime. Considering ion temperature effects, it is found that the impact of finite Larmor radius effects significantly reduces the growth rate of the drift-Alfven wave instability with synergistic effects of high beta stabilization and Landau resonance. [ABSTRACT FROM AUTHOR]

Published
2015
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29. Electromagnetic effects on dynamics of high-beta filamentary structures.

Author

Wonjae Lee, Umansky, Maxim V., Angus, J. R., and Krasheninnikov, Sergei I.

Subjects
HIGH-beta plasma, ELECTROMAGNETIC fields, PLASMA pressure, CURVATURE, PLASMA currents, HEAT exchangers
Abstract

The impacts of the electromagnetic effects on blob dynamics are considered. Electromagnetic BOUT++ simulations on seeded high-beta blobs demonstrate that inhomogeneity of magnetic curvature or plasma pressure along the filament leads to bending of the blob filaments and the magnetic field lines due to increased propagation time of plasma current (Alfven time). The bending motion can enhance heat exchange between the plasma facing materials and the inner scrape-off layer (SOL) region. The effects of sheath boundary conditions on the part of the blob away from the boundary are also diminished by the increased Alfven time. Using linear analysis and BOUT++ simulations, it is found that electromagnetic effects in high temperature and high density plasmas reduce the growth rate of resistive drift wave instability when resistivity drops below a certain value. The blobs temperature decreases in the course of its motion through the SOL and so the blob can switch from the electromagnetic to the electrostatic regime where resistive drift waves become important again [ABSTRACT FROM AUTHOR]

Published
2015
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