Your search keyword '"J. R. Angus"' showing total 14 results

1. First Experiments and Radiographs on the MegaJOuLe Neutron Imaging Radiography (MJOLNIR) Dense Plasma Focus

Author

J. R. Angus, I. Holod, Clement Goyon, S.A. Hawkins, M. G. Anderson, James Mitrani, Yuri Podpaly, A. Link, E. Koh, Drew Higginson, S. Chapman, D. Max, A. Povilus, Owen B. Drury, M. McMahon, Andrea Schmidt, C. M. Cooper, D. Van Lue, and E. Anaya

Subjects

Physics, Nuclear and High Energy Physics, Range (particle radiation), Dense plasma focus, business.industry, Neutron imaging, Detector, Plasma, Pulsed power, Condensed Matter Physics, Optics, Physics::Plasma Physics, Neutron, Coaxial, business

Abstract

A dense plasma focus (DPF) is a relatively compact coaxial plasma gun, which completes its discharge as a Z-pinch. These devices are designed to operate at a variety of scales to produce short (

Published

2021

2. Laser-metal interaction dynamics during additive manufacturing resolved by detection of thermally-induced electron emission

Author

Gabe Guss, Manyalibo J. Matthews, John C. Fuller, Aiden A. Martin, Saad A. Khairallah, J. R. Angus, and Philip J. Depond

Subjects

0303 health sciences, Fusion, Materials science, Laser scanning, business.industry, Thermionic emission, 02 engineering and technology, Electron, 021001 nanoscience & nanotechnology, Thermal conduction, Laser, law.invention, 03 medical and health sciences, Mechanics of Materials, law, Thermal, Optoelectronics, General Materials Science, 0210 nano-technology, business, Keyhole, 030304 developmental biology

Abstract

In situ monitoring is required to improve the understanding and increase the reliability of additive manufacturing methods such as laser powder bed fusion (LPBF). Current diagnostic methods for LPBF capture optical images, X-ray radiographs, or measure the emission of thermal or acoustic signals from the component. Herein, a methodology based on the thermal emission of electrons - thermionic emission - from the metal surface during LPBF is proposed which can resolve laser-material interaction dynamics. The high sensitivity of thermionic emission to surface temperature and surface morphology is revealed to enable precise determination of the transition between conduction and keyhole mode melting regimes. Increases in thermionic emission are correlated to laser scanning conditions that give rise to pore formation and regions where surface defects are pronounced. The information presented here is a critical step in furthering our understanding and validation of laser-based metal additive manufacturing. In situ monitoring during additive manufacturing is an emerging approach for validating the quality of built parts. Here, thermal emission of electrons from the metal surface during laser processing is shown to be an effective indicator of conduction or keyhole melting regimes.

Published

2020

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

Author

Jeff Narkis, David Housley, F. Conti, A. Link, J. R. Angus, Farhat Beg, and Eric N. Hahn

Subjects

010302 applied physics, Debye sheath, Yield (engineering), Materials science, Dense plasma focus, Electrical breakdown, General Physics and Astronomy, Insulator (electricity), 02 engineering and technology, Electron, 021001 nanoscience & nanotechnology, 01 natural sciences, Molecular physics, symbols.namesake, Phase (matter), 0103 physical sciences, Pinch, symbols, 0210 nano-technology

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.

Published

2021

4. 1D kinetic study of pinch formation in a dense plasma focus: Transition from collisional to collisionless regimes

Author

J. R. Angus, A. Link, and Andrea Schmidt

Subjects

Physics, Dense plasma focus, Mean free path, Radius, Condensed Matter Physics, Kinetic energy, 01 natural sciences, 010305 fluids & plasmas, Deuterium, Physics::Plasma Physics, 0103 physical sciences, Pinch, Neutron, Atomic physics, 010306 general physics, Dimensionless quantity

Abstract

The pinch-formation stage of a deuterium dense plasma focus, and associated “shock-flash” neutron yield, is studied using 1D kinetic simulations considering a plasma column with initial pressure P, initial radius R, and the compression to be driven by a constant current I. The relative behavior of the compression is shown to be similar for fixed ratios of the characteristic ion mean free path to the radius of the plasma column at stagnation, λ s t / R s t. This dimensionless parameter is shown to scale like I 4 / ( P 3 R 5 ). The compression ratio, R / R s t, is found to be a minimum when λ s t / R s t ≈ 1 and is the largest in the collisionless limit where λ s t ≫ R s t. This behavior is in contrast to the analogous planar pinch where R / R s t decreases from one constant for λ s t / R s t ≪ 1 to a smaller constant for λ s t / R s t ≫ 1. The yield in the collisionless regime is shown to fall between the two well-known I4 scaling laws. Furthermore, this regime exhibits qualities that potentially make it appealing for radiography applications, such as increased localization in time and space of the neutron formation.

Published

2021

5. Edge Simulation Laboratory

Author

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

Subjects

Materials science, Optics, business.industry, Edge (geometry), business

Published

2018

6. Electromagnetic effects on plasma blob-filament transport

Author

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

Subjects

Physics, Resistive touchscreen, Nuclear and High Energy Physics, Wave turbulence, Atmospheric-pressure plasma, Plasma, Mechanics, Curvature, Protein filament, Classical mechanics, Materials Science(all), Nuclear Energy and Engineering, Physics::Plasma Physics, Beta (plasma physics), Physics::Space Physics, General Materials Science, Boundary value problem

Abstract

Both microscopic and macroscopic impacts of the electromagnetic effects on blob dynamics are considered. Linear stability analysis and nonlinear BOUT++ simulations demonstrate that electromagnetic effects in high temperature or high beta plasmas suppress the resistive drift wave turbulence in the blob when resistivity drops below a certain value. In the course of blob’s motion in the SOL its temperature is reduced, which leads to enhancement of resistive effects, so the blob can switch from electromagnetic to electrostatic regime, where resistive drift wave turbulence become important. It is found that inhomogeneity of magnetic curvature or plasma pressure along the filament length leads to bending of the high-beta blob filaments. This is caused by the increase of the propagation time of plasma current (Alfven time) in higher-density plasma. The effects of sheath boundary conditions on the part of the blob away from the boundary are also diminished by the increased Alfven time.

Published

2015

7. Drift-ideal magnetohydrodynamic simulations of m = 0 modes in Z-pinch plasmas

Author

Mikhail Dorf, J. R. Angus, and V. I. Geyko

Subjects

Physics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Ion, Nonlinear system, Entropy (classical thermodynamics), Heat flux, Physics::Plasma Physics, Speed of sound, 0103 physical sciences, Magnetohydrodynamic drive, Magnetohydrodynamics, Atomic physics, 010306 general physics, Adiabatic process

Abstract

The effects of m = 0 modes on equilibrium Z-pinch plasmas are studied in this paper using a drift-ideal magnetohydrodynamic (MHD) model. The model equations are an extension of ideal MHD to include finite-ion-inertial-length/cyclotron-frequency (Ωi) effects in Ohm's law and in the electron and ion heat transport equations. The linear modes contained in this model include the ideal interchange (sausage) mode and in the magnetized limit, Ωiτi≫1 with τi the ion collision time, nonideal entropy modes. It is well known that these two modes are decoupled in the kρs≪1 limit, where k is the axial mode number and ρs=cs/Ωi is the gyro-Bohm scale with cs the sound speed [B. Kadomtsev, Sov. Phys. JETP-USSR 10, 780 (1960)]. For Bennett equilibrium profiles, it is shown that the regions of stability for both modes are completely governed by the adiabatic coefficient γ in these limits. Equilibria with Bennett profiles are stable to entropy modes for γ 2. However, these modes are no longer decoupled when kρs≳1. The simulation results of the fully nonlinear set of equations in the magnetized limit show that seeded modes with kρs≳1 and γ = 5/3 display the characteristics of both ideal and entropy modes. The general heat flux for both ions and electrons as a function of the species magnetization is retained in the model. Both the linear and nonlinear behaviors of seeded modes for kρs≳1 display a strong dependence on the magnetization of the ions. The growth rate increases linearly with k at large kρs when the ions are magnetized but decreases with increasing k when Ωiτi≲1.The effects of m = 0 modes on equilibrium Z-pinch plasmas are studied in this paper using a drift-ideal magnetohydrodynamic (MHD) model. The model equations are an extension of ideal MHD to include finite-ion-inertial-length/cyclotron-frequency (Ωi) effects in Ohm's law and in the electron and ion heat transport equations. The linear modes contained in this model include the ideal interchange (sausage) mode and in the magnetized limit, Ωiτi≫1 with τi the ion collision time, nonideal entropy modes. It is well known that these two modes are decoupled in the kρs≪1 limit, where k is the axial mode number and ρs=cs/Ωi is the gyro-Bohm scale with cs the sound speed [B. Kadomtsev, Sov. Phys. JETP-USSR 10, 780 (1960)]. For Bennett equilibrium profiles, it is shown that the regions of stability for both modes are completely governed by the adiabatic coefficient γ in these limits. Equilibria with Bennett profiles are stable to entropy modes for γ 2. However,...

Published

2019

8. Gyrokinetic simulations of m = 0 mode in sheared flow Z-pinch plasmas

Author

V. I. Geyko, Mikhail Dorf, and J. R. Angus

Subjects

Physics, Wavelength, Physics::Plasma Physics, Gyroradius, Z-pinch, Dispersion relation, Rotational symmetry, Mechanics, Magnetohydrodynamics, Condensed Matter Physics, Kinetic energy, Linear stability

Abstract

Axisymmetric stability properties of sheared flow Z-pinch plasmas are studied by making use of the gyrokinetic approximation in the long-wavelength limit. Numerical simulations are carried out with the high-order finite-volume code COntinuum Gyrokinetic Edge New Technology (COGENT) and are analyzed for the parameters characteristic of the FuZE experiment. Reduction of the linear growth rate with increasing shear is observed, and the results are elucidated by making use of a local dispersion relation analysis. In addition, COGENT simulations are compared with fully kinetic particle-in-cell simulations, and with an ideal magnetohydrodynamics (MHD) model. Good agreement between the gyrokinetic and fully kinetic results for the linear stability is found, with the gyrokinetic model requiring much less computational time due to its ability to step over particle gyroperiod. The ideal MHD model is found to be consistent with the kinetic models in the long-wavelength part of the spectra (kρi), while failing to adequately predict short-scale (kρi) stability. Here, k is the axial wavelength vector and ρi is the ion gyroradius.

Published

2019

9. Progress with the COGENT Edge Kinetic Code: Collision Operator Options

Author

P. McCorquodale, J. R. Angus, T.D. Rognlien, Sergei Krasheninnikov, Daniel F. Martin, J. C. Compton, M. R. Dorr, Ronald H. Cohen, Phillip Colella, and Mikhail Dorf

Subjects

Physics, Discretization, Continuum (topology), Operator (physics), Lorentz transformation, Energy–momentum relation, Condensed Matter Physics, Kinetic energy, symbols.namesake, Theoretical physics, Classical mechanics, symbols, Electric potential, Poisson's equation

Abstract

In this study, COGENT is a continuum gyrokinetic code for edge plasmas being developed by the Edge Simulation Laboratory collaboration. The code is distinguished by application of the fourth order conservative discretization, and mapped multiblock grid technology to handle the geometric complexity of the tokamak edge. It is written in v∥-μ (parallel velocity – magnetic moment) velocity coordinates, and making use of the gyrokinetic Poisson equation for the calculation of a self-consistent electric potential. In the present manuscript we report on the implementation and initial testing of a succession of increasingly detailed collision operator options, including a simple drag-diffusion operator in the parallel velocity space, Lorentz collisions, and a linearized model Fokker-Planck collision operator conserving momentum and energy (© 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim)

Published

2012

10. Maximizing neutron yields by scaling hollow diameter of a dense plasma focus anode

Author

A. Povilus, C. M. Cooper, Andrea Schmidt, J. R. Angus, Clement Goyon, Drew Higginson, James Mitrani, Yuri Podpaly, Brian Shaw, S. Chapman, A. Link, and J. X. Liu

Subjects

Void (astronomy), Materials science, Dense plasma focus, General Physics and Astronomy, chemistry.chemical_element, 01 natural sciences, Copper, 010305 fluids & plasmas, Anode, chemistry, Sputtering, 0103 physical sciences, Neutron, Composite material, 010306 general physics, Quartz, Scaling

Abstract

Experiments were performed to maximize the neutron yield from a 2 kJ dense plasma focus (DPF) and characterize the amount of copper sputtered from the surface of an anode by varying the diameter of the anodes’ on-axis hollow. The hollow is a void in the copper material along the longitudinal axis of the anode. All the anodes had an outer diameter of 1.2 in. and the diameter of the hollow varied from 0 in. (no hollow) to 1 in. The anodes with a hollow produced a greater number of neutrons per discharge than the anode without a hollow. Over 40 discharges, the hollow anode that yielded the most neutrons (9.1 ±0.4 ×10 6 neutrons per discharge produced with the 0.75 in. hollow) produced >6 times more neutrons than the anode with no hollow. A qualitative observation of the anodes after 130 discharges showed less surface damage on anodes with a larger hollow. Quantitative sputter measurements were performed by characterizing the amount of copper sputtered onto on-axis quartz targets for three newly machined anodes, each with a particular hollow diameter. The quantitative results matched the qualitative observations: the copper sputter was reduced using larger hollows. The largest hollow sputtered 17 ±1.0 nm/sr/discharge of copper, a reduction of 69 % compared to the anode with the most damage.Experiments were performed to maximize the neutron yield from a 2 kJ dense plasma focus (DPF) and characterize the amount of copper sputtered from the surface of an anode by varying the diameter of the anodes’ on-axis hollow. The hollow is a void in the copper material along the longitudinal axis of the anode. All the anodes had an outer diameter of 1.2 in. and the diameter of the hollow varied from 0 in. (no hollow) to 1 in. The anodes with a hollow produced a greater number of neutrons per discharge than the anode without a hollow. Over 40 discharges, the hollow anode that yielded the most neutrons (9.1 ±0.4 ×10 6 neutrons per discharge produced with the 0.75 in. hollow) produced >6 times more neutrons than the anode with no hollow. A qualitative observation of the anodes after 130 discharges showed less surface damage on anodes with a larger hollow. Quantitative sputter measurements were performed by characterizing the amount of copper sputtered onto on-axis quartz targets for three newly machined ano...

Published

2018

11. Effect of drift waves on plasma blob dynamics

Author

J. R. Angus, Maxim Umansky, and Sergei Krasheninnikov

Subjects

Convection, Physics, Plane (geometry), Astrophysics::High Energy Astrophysical Phenomena, Wave turbulence, General Physics and Astronomy, Magnetic confinement fusion, Astrophysics::Cosmology and Extragalactic Astrophysics, Mechanics, Plasma, Magnetic field, Radial velocity, Classical mechanics, Physics::Plasma Physics, Line (formation)

Abstract

Most of the work to date on plasma blobs found in the edge region of magnetic confinement devices is limited to 2D theory and simulations which ignore the variation of blob parameters along the magnetic field line. However, if the 2D convective rate of blobs is on the order of the growth rate of unstable drift waves, then drift wave turbulence can drastically alter the dynamics of blobs from that predicted by 2D theory. The density gradients in the drift plane that characterize the blob are mostly depleted during the nonlinear stage of drift waves resulting in a much more diffuse blob with a greatly reduced radial velocity. Sheath connected plasma blobs driven by effective gravity forces are considered in this Letter and it is found that the effects of resistive drift waves occur at earlier stages in the 2D motion for smaller blobs and in systems with a smaller effective gravity force. These conclusions are supported numerically by a direct comparison of 2D and 3D seeded blob simulations.

Published

2012

12. Visualization of Magnetic Field Penetration in Multicomponent Plasma

Author

Stephen B. Swanekamp, J. R. Angus, P.F. Ottinger, Andrew Richardson, and Joseph W. Schumer

Subjects

Physics, Nuclear and High Energy Physics, Dense plasma focus, Condensed matter physics, Waves in plasmas, Plasma, equipment and supplies, Condensed Matter Physics, Computational physics, Magnetic field, Plasma window, Physics::Plasma Physics, Physics::Space Physics, Electromagnetic electron wave, Inductively coupled plasma, human activities, Magnetosphere particle motion

Abstract

Magnetic pushing of plasmas is an important fundamental phenomena in plasma physics. In the presence of strong plasma-density gradients, Hall-magnetohydrodynamics forces can lead to penetration of the magnetic field into the plasma. For multicomponent plasmas, simulations show that the magnetic field can penetrate the heavy-ion component of the plasma while simultaneously pushing the light ions. Images are presented of the simulated plasma densities showing the resulting species separation.

Published

2014

13. Controlling hollow relativistic electron beam orbits with an inductive current divider

Author

G. Cooperstein, P.F. Ottinger, Ian M. Rittersdorf, J.W. Schumer, S.B. Swanekamp, J. C. Zier, D.D. Hinshelwood, J. R. Angus, A. S. Richardson, and B.V. Weber

Subjects

Physics, Beam diameter, business.industry, Condensed Matter Physics, Current divider, Inductance, Optics, Physics::Accelerator Physics, Relativistic electron beam, M squared, Laser beam quality, Atomic physics, business, Current density, Beam (structure)

Abstract

A passive method for controlling the trajectory of an intense, hollow electron beam is proposed using a vacuum structure that inductively splits the beam's return current. A central post carries a portion of the return current (I1), while the outer conductor carries the remainder (I2). An envelope equation appropriate for a hollow electron beam is derived and applied to the current divider. The force on the beam trajectory is shown to be proportional to (I2-I1), while the average force on the envelope (the beam width) is proportional to the beam current Ib = (I2 + I1). The values of I1 and I2 depend on the inductances in the return-current path geometries. Proper choice of the return-current geometries determines these inductances and offers control over the beam trajectory. Solutions using realistic beam parameters show that, for appropriate choices of the return-current-path geometry, the inductive current divider can produce a beam that is both pinched and straightened so that it approaches a target at...

Published

2015

14. Electromagnetic effects on dynamics of high-beta filamentary structures

Author

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

Subjects

Physics, Physics::Plasma Physics, Wave propagation, Beta (plasma physics), Atmospheric-pressure plasma, Boundary value problem, Plasma, Mechanics, Atomic physics, Electric current, Condensed Matter Physics, Instability, Magnetic field

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.

Published

2015