Your search keyword '"Schaeffer D"' showing total 15 results

1. Kinetic simulations comparing quasi-parallel and quasi-perpendicular piston-driven collisionless shock dynamics in magnetized laboratory plasmas.

Author

Pongkitiwanichakul, P., Schaeffer, D. B., Fox, W., Ruffolo, D., Donaghy, J., and Germaschewski, K.

Subjects

*COLLISIONLESS plasmas, *MAGNETIC fields, *ION temperature, *LABORATORIES, *REFORMATION

Abstract

Magnetized collisionless shocks are common in astrophysical systems, and scaled versions can be created in laboratory experiments by utilizing laser-driven piston plasmas to create these shocks in a magnetized background plasma. A key parameter for these experiments is the angle θB between the shock propagation direction and the background magnetic field. We performed quasi-1D piston-driven shock simulations to explore shock formation, evolution, and key observables relevant to laboratory experiments for a range of shock angles between θ B = 90 ° to θ B = 30 °. Our results show that the spatial and temporal scales of shock formation for all angles considered are similar when expressed in terms of the perpendicular component of the magnetic field. In a steady state, ion and electron temperatures become more isotropic, and the electron-to-ion temperature ratio is higher for smaller θB. At θ B = 30 ° , ion heating parallel to the magnetic field becomes dominant, associated with more ions being reflected at one discontinuity and subsequently trapped by the next discontinuity due to shock reformation. [ABSTRACT FROM AUTHOR]

Published

2024

2. Strong collisionless coupling between an unmagnetized driver plasma and a magnetized background plasma.

Author

Cruz, F. D., Schaeffer, D. B., Cruz, F., and Silva, L. O.

Subjects

*CORONAL mass ejections, *COLLISIONLESS plasmas, *SUPERNOVA remnants, *PLASMA astrophysics

Abstract

Fast-exploding plasmas traveling though magnetized, collisionless plasmas can occur in a variety of physical systems, such as supernova remnants, coronal mass ejections, and laser-driven laboratory experiments. To study these systems, it is important to understand the coupling process between the plasmas. In this work, we develop a semi-analytical model of the parameters that characterize the strong collisionless coupling between an unmagnetized driver plasma and a uniformly and perpendicularly magnetized background plasma. In particular, we derive analytical expressions that describe the characteristic diamagnetic cavity and magnetic compression of these systems, such as their corresponding velocities, the compression ratio, and the maximum size of the cavity. The semi-analytical model is compared with collisionless 1D particle-in-cell simulations and experimental results with laser-driven plasmas. The model allows us to provide bounds for parameters that are otherwise difficult to diagnose in experiments with similar setups. [ABSTRACT FROM AUTHOR]

Published

2023

3. High repetition rate mapping of the interaction between a laser plasma and magnetized background plasma via laser induced fluorescence.

Author

Dorst, R. S., Schaeffer, D. B., Le, A., Pilgram, J. J., Constantin, C. G., Vincena, S., Tripathi, S. K. P., Winske, D., Larson, D., Cowee, M., and Niemann, C.

Subjects

*LASER-plasma interactions, *LASER plasmas, *COLLISIONLESS plasmas, *LASER-induced breakdown spectroscopy, *DISTRIBUTION (Probability theory), *LASER-induced fluorescence, *PLASMA flow, *ION migration & velocity

Abstract

The laminar coupling of energy between a laser-produced plasma and a background magnetized plasma was investigated via planar laser induced fluorescence diagnostic and magnetic flux probes. Experiments performed on the Large Plasma Device at the University of California, Los Angeles, mapped out the two-dimensional spatiotemporal evolution of the laser-plasma (debris) ion velocity distribution function (VDF) to assess debris-background coupling in a sub-Alfvénic regime. The acquisition of these data necessitates high repetition rate (1 Hz) as each dataset is the accumulation of thousands of laser shots, which would not be feasible in single-shot experiments. Fully kinetic, three-dimensional particle-in-cell simulations are compared to the measured VDFs to provide a framework in which we can understand the coupling of a sub-Alfvénic plasma flow through a preformed, magnetized plasma. The simulations display the same departure from the expected gyromotion of the debris plasma as observed in the experimental data, and in conjunction with the measured magnetic field traces, have led to the direct observation of the collisionless coupling via laminar fields. [ABSTRACT FROM AUTHOR]

Published

2022

4. Laser-driven, ion-scale magnetospheres in laboratory plasmas. I. Experimental platform and first results.

Author

Schaeffer, D. B., Cruz, F. D., Dorst, R. S., Cruz, F., Heuer, P. V., Constantin, C. G., Pribyl, P., Niemann, C., Silva, L. O., and Bhattacharjee, A.

Subjects

*MAGNETOSPHERE, *PLASMA physics, *PLASMA flow, *MAGNETIC dipoles, *MAGNETOPAUSE, *MAGNETIC flux, *COLLISIONLESS plasmas

Abstract

Magnetospheres are a ubiquitous feature of magnetized bodies embedded in a plasma flow. While large planetary magnetospheres have been studied for decades by spacecraft, ion-scale "mini" magnetospheres can provide a unique environment to study kinetic-scale, collisionless plasma physics in the laboratory to help validate models of larger systems. In this work, we present preliminary experiments of ion-scale magnetospheres performed on a unique high-repetition-rate platform developed for the Large Plasma Device at the University of California, Los Angeles. The experiments utilize a high-repetition-rate laser to drive a fast plasma flow into a pulsed dipole magnetic field embedded in a uniform magnetized background plasma. 2D maps of the magnetic field with high spatial and temporal resolution are measured with magnetic flux probes to examine the evolution of magnetosphere and current density structures for a range of dipole and upstream parameters. The results are further compared to 2D particle-in-cell simulations to identify key observational signatures of the kinetic-scale structures and dynamics of the laser-driven plasma. We find that distinct 2D kinetic-scale magnetopause and diamagnetic current structures are formed at higher dipole moments, and their locations are consistent with predictions based on pressure balances and energy conservation. [ABSTRACT FROM AUTHOR]

Published

2022

5. Kinetic simulation of magnetic field generation and collisionless shock formation in expanding laboratory plasmas.

Author

Fox, W., Matteucci, J., Moissard, C., Schaeffer, D. B., Bhattacharjee, A., Germaschewski, K., and Hu, S. X.

Subjects

MAGNETIC fields, COLLISIONLESS plasmas, PLASMA gases, PLASMA astrophysics, PLASMA instabilities, ION flow dynamics, HALL effect, NERNST effect

Abstract

Recent laboratory experiments with laser-produced plasmas have observed and studied a number of fundamental physical processes relevant to magnetized astrophysical plasmas, including magnetic reconnection, collisionless shocks, and magnetic field generation by Weibel instability, opening up new experimental platforms for laboratory astrophysics. We develop a fully kinetic simulation model for first-principles simulation of these systems including the dynamics of magnetic fields—magnetic field generation by the Biermann battery effect or Weibel instability; advection by the ion flow, Hall effect, and Nernst effect; and destruction of the field by dissipative mechanisms. Key dimensionless parameters describing the system are derived for scaling between kinetic simulation, recent experiments, and astrophysical plasmas. First, simulations are presented which model Biermann battery magnetic field generation in plasmas expanding from a thin target. Ablation of two neighboring plumes leads to the formation of a current sheet as the opposing Biermann-generated fields collide, modeling recent laser-driven magnetic reconnection experiments. Second, we simulate recent experiments on collisionless magnetized shock generation, by expanding a piston plasma into a pre-magnetized ambient plasma. For parameters considered, the Biermann effect generates additional magnetic fields in the curved shock front and thereby increases shock particle reflection. Both cases show the importance of kinetic processes in the interaction of plasmas with magnetic fields and open opportunities to benchmark these important processes through comparison of theory and experiments. [ABSTRACT FROM AUTHOR]

Published

2018

6. Laboratory study of collisionless coupling between explosive debris plasma and magnetized ambient plasma.

Author

Bondarenko, A. S., Schaeffer, D. B., Everson, E. T., Clark, S. E., Lee, B. R., Constantin, C. G., Vincena, S., Van Compernolle, B., Tripathi, S. K. P., Winske, D., and Niemann, C.

Subjects

*COLLISIONLESS plasmas, *LASER plasmas, *EMISSION spectroscopy, *PLASMA flow, *DOPPLER effect

Abstract

The explosive expansion of a localized plasma cloud into a relatively tenuous, magnetized, ambient plasma characterizes a variety of astrophysical and space phenomena. In these rarified environments, collisionless electromagnetic processes rather than Coulomb collisions typically mediate the transfer of momentum and energy from the expanding "debris" plasma to the surrounding ambient plasma. In an effort to better understand the detailed physics of collisionless coupling mechanisms, compliment in situ measurements of space phenomena, and provide validation of previous computational and theoretical work, the present research jointly utilizes the Large Plasma Device and the Raptor laser facility at the University of California, Los Angeles to study the super-Alfvénic, quasi-perpendicular expansion of laser-produced carbon (C) and hydrogen (H) debris plasma through preformed, magnetized helium (He) ambient plasma via a variety of diagnostics, including emission spectroscopy, wavelength-filtered imaging, and a magnetic flux probe. Doppler shifts detected in a He1+ ion spectral line indicate that the ambient ions initially accelerate transverse to both the debris plasma flow and the background magnetic field. A qualitative analysis in the framework of a "hybrid" plasma model (kinetic ions and inertia-less fluid electrons) demonstrates that the ambient ion trajectories are consistent with the large-scale laminar electric field expected to develop due to the expanding debris. In particular, the transverse ambient ion motion provides direct evidence of Larmor coupling, a collisionless momentum exchange mechanism that has received extensive theoretical and numerical investigation. In order to quantitatively evaluate the observed Doppler shifts, a custom simulation utilizing a detailed model of the laser-produced debris plasma evolution calculates the laminar electric field and computes the initial response of a distribution of ambient test ions. A synthetic Doppler-shifted spectrum constructed from the simulated test ion velocities excellently reproduces the experimental measurements, verifying that the observed ambient ion motion corresponds to collisionless coupling through the laminar electric field. [ABSTRACT FROM AUTHOR]

Published

2017

7. On the generation of magnetized collisionless shocks in the large plasma device.

Author

Schaeffer, D. B., Winske, D., Larson, D. J., Cowee, M. M., Constantin, C. G., Bondarenko, A. S., Clark, S. E., and Niemann, C.

Subjects

*COLLISIONLESS plasmas, *PLASMA gases, *IONIZING shock waves, *MAGNETIC fields, *MICROPHYSICS

Abstract

Collisionless shocks are common phenomena in space and astrophysical systems, and in many cases, the shocks can be modeled as the result of the expansion of a magnetic piston though a magnetized ambient plasma. Only recently, however, have laser facilities and diagnostic capabilities evolved sufficiently to allow the detailed study in the laboratory of the microphysics of piston-driven shocks. We review experiments on collisionless shocks driven by a laser-produced magnetic piston undertaken with the Phoenix laser laboratory and the Large Plasma Device at the University of California, Los Angeles. The experiments span a large parameter space in laser energy, background magnetic field, and ambient plasma properties that allow us to probe the physics of piston-ambient energy coupling, the launching of magnetosonic solitons, and the formation of subcritical shocks. The results indicate that piston-driven magnetized collisionless shocks in the laboratory can be characterized with a small set of dimensionless formation parameters that place the formation process in an organized and predictive framework. [ABSTRACT FROM AUTHOR]

Published

2017

8. Experimental study of subcritical laboratory magnetized collisionless shocks using a laser-driven magnetic piston.

Author

Schaeffer, D. B., Everson, E. T., Bondarenko, A. S., Clark, S. E., Constantin, C. G., Winske, D., Gekelman, W., and Niemann, C.

Subjects

*MAGNETIZATION, *COLLISIONLESS plasmas, *ELECTROMAGNETIC coupling, *PLASMA shock waves, *SIMULATION methods & models

Abstract

Recent experiments at the University of California, Los Angeles have successfully generated subcritical magnetized collisionless shocks, allowing new laboratory studies of shock formation relevant to space shocks. The characteristics of these shocks are compared with new data in which no shock or a pre-shock formed. The results are consistent with theory and 2D hybrid simulations and indicate that the observed shock or shock-like structures can be organized into distinct regimes by coupling strength. With additional experiments on the early time parameters of the laser plasma utilizing Thomson scattering, spectroscopy, and fast-gate filtered imaging, these regimes are found to be in good agreement with theoretical shock formation criteria. [ABSTRACT FROM AUTHOR]

Published

2015

9. Laser-driven, magnetized quasi-perpendicular collisionless shocks on the Large Plasma Device.

Author

Schaeffer, D. B., Everson, E. T., Bondarenko, A. S., Clark, S. E., Constantin, C. G., Vincena, S., Van Compernolle, B., Tripathi, S. K. P., Winske, D., Gekelman, W., and Niemann, C.

Subjects

*PLASMA devices, *LASERS, *COLLISIONLESS plasmas, *MICROPHYSICS, *SIMULATION methods & models, *MACH number

Abstract

The interaction of a laser-driven super-Alfvénic magnetic piston with a large, preformed magnetized ambient plasma has been studied by utilizing a unique experimental platform that couples the Raptor kJ-class laser system [Niemann et al., J. Instrum. 7, P03010 (2012)] to the Large Plasma Device [Gekelman et al., Rev. Sci. Instrum. 62, 2875 (1991)] at the University of California, Los Angeles. This platform provides experimental conditions of relevance to space and astrophysical magnetic collisionless shocks and, in particular, allows a detailed study of the microphysics of shock formation, including piston-ambient ion collisionless coupling. An overview of the platform and its capabilities is given, and recent experimental results on the coupling of energy between piston and ambient ions and the formation of collisionless shocks are presented and compared to theoretical and computational work. In particular, a magnetosonic pulse consistent with a low-Mach number collisionless shock is observed in a quasi-perpendicular geometry in both experiments and simulations. [ABSTRACT FROM AUTHOR]

Published

2014

10. Hybrid simulation of shock formation for super-Alfvénic expansion of laser ablated debris through an ambient, magnetized plasma.

Author

Clark, S. E., Winske, D., Schaeffer, D. B., Everson, E. T., Bondarenko, A. S., Constantin, C. G., and Niemann, C.

Subjects

HYBRID computer simulation, PLASMA Alfven waves, LASER ablation, MAGNETIZATION, PLASMA physics, TWO-dimensional models, COLLISIONLESS plasmas

Abstract

Two-dimensional hybrid simulations of perpendicular collisionless shocks are modeled after potential laboratory conditions that are attainable in the LArge Plasma Device (LAPD) at the University of California, Los Angeles Basic Plasma Science Facility. The kJ class 1053 nm Nd:Glass Raptor laser will be used to ablate carbon targets in the LAPD with on-target energies of 100-500 J. The ablated debris ions will expand into ambient, partially ionized hydrogen or helium. A parameter study is performed via hybrid simulation to determine possible conditions that could lead to shock formation in future LAPD experiments. Simulation results are presented along with a comparison to an analytical coupling parameter. [ABSTRACT FROM AUTHOR]

Published

2013

11. Collisionless interaction of an energetic laser produced plasma with a large magnetoplasma.

Author

Constantin, C., Gekelman, W., Pribyl, P., Everson, E., Schaeffer, D., Kugland, N., Presura, R., Neff, S., Plechaty, C., Vincena, S., Collette, A., Tripathi, S., Muniz, M., and Niemann, C.

Subjects

COLLISIONLESS plasmas, LASER plasmas, PLASMA devices, MAGNETOHYDRODYNAMIC waves, PLASMA astrophysics

Abstract

We have commissioned a high-energy glass-laser at the Large Plasma Device (LAPD) to study the interaction of a dense laser-produced plasma with a large (17 m) magnetized plasma. First experiments with an energy of the laser blow-off an order of magnitude higher than previous work (Gekelman et al. in J. Geophys. Res. 108(A7):1281, ) produced large amplitude Alfvén waves ( δ B ⊥/ B0≈15%). We will discuss the potential of this facility for collisionless laboratory astrophysics experiments. [ABSTRACT FROM AUTHOR]

Published

2009

12. Observations of a field-aligned ion/ion-beam instability in a magnetized laboratory plasma.

Author

Heuer, P. V., Weidl, M. S., Dorst, R. S., Schaeffer, D. B., Bondarenko, A. S., Tripathi, S. K. P., Van Compernolle, B., Vincena, S., Constantin, C. G., Niemann, C., and Winske, D.

Subjects

PLASMA magnetism, ION beams, PARTICLE beam instabilities, COLLISIONLESS plasmas, MAGNETIC fields, ELECTROMAGNETIC waves

Abstract

Collisionless coupling between super Alfvénic ions and an ambient plasma parallel to a background magnetic field is mediated by a set of electromagnetic ion/ion-beam instabilities including the resonant right hand instability (RHI). To study this coupling and its role in parallel shock formation, a new experimental configuration at the University of California, Los Angeles utilizes high-energy and high-repetition-rate lasers to create a super-Alfvénic field-aligned debris plasma within an ambient plasma in the Large Plasma Device. We used a time-resolved fluorescence monochromator and an array of Langmuir probes to characterize the laser plasma velocity distribution and density. The debris ions were observed to be sufficiently super-Alfvénic and dense to excite the RHI. Measurements with magnetic flux probes exhibited a right-hand circularly polarized frequency chirp consistent with the excitation of the RHI near the laser target. We compared measurements to 2D hybrid simulations of the experiment. [ABSTRACT FROM AUTHOR]

Published

2018

13. Magnetic field measurements in low density plasmas using paramagnetic Faraday rotator glass.

Author

Clark, S. E., Schaeffer, D. B., Bondarenko, A. S., Everson, E. T., Constantin, C. G., and Niemann, C.

Subjects

*MAGNETIC fields, *PLASMA density, *FARADAY effect, *BOROSILICATES, *HELIUM plasmas, *OPTICAL polarization, *COLLISIONLESS plasmas

Abstract

Paramagnetic Faraday rotator glass (rare-earth doped borosilicate) with a high Verdet constant will be used to measure the magnetic field inside of low density Helium plasmas (Te ∼ 5 eV, Ti ∼ 1 eV) with a density of n ∼ 1012 cm-3. Linearly polarized light is sent through the glass such that the plane of polarization is rotated by an angle that depends on the strength of the magnetic field in the direction of propagation and the length of the crystal (6 mm). The light is then passed into an analyzer and photo-detector setup to determine the change in polarization angle. This setup can detect magnetic fields up to 5 kG with a resolution of <5 G and a temporal resolution on the order of a nanosecond. The diagnostic will be used to characterize the structure and evolution of laser-driven collisionless shocks in large magnetized plasmas. [ABSTRACT FROM AUTHOR]

Published

2012

14. Generation of magnetized collisionless shocks by a novel, laser-driven magnetic piston.

Author

Schaeffer, D. B., Everson, E. T., Winske, D., Constantin, C. G., Bondarenko, A. S., Morton, L. A., Flippo, K. A., Montgomery, D. S., Gaillard, S. A., and Niemann, C.

Subjects

*MAGNETIZATION, *COLLISIONLESS plasmas, *MECHANICAL shock, *LASER beams, *PHYSICS experiments, *NUCLEAR facilities

Abstract

We present experiments on the Trident laser facility at Los Alamos National Laboratory which demonstrate key elements in the production of laser-driven, magnetized, laboratory-scaled astrophysical collisionless shocks. These include the creation of a novel magnetic piston to couple laser energy to a background plasma and the generation of a collisionless shock precursor. We also observe evidence of decoupling between a laser-driven fast ion population and a background plasma, in contrast to the coupling of laser-ablated slow ions with background ions through the magnetic piston. 2D hybrid simulations further support these developments and show the coupling of the slow to ambient ions, the formation of a magnetic and density compression pulses consistent with a collisionless shock, and the decoupling of the fast ions. [ABSTRACT FROM AUTHOR]

Published

2012

15. Enhanced collisionless shock formation in a magnetized plasma containing a density gradient.

Author

Clark, S. E., Everson, E. T., Schaeffer, D. B., Bondarenko, A. S., Constantin, C. G., Niemann, C., and Winske, D.

Subjects

*COLLISIONLESS plasmas, *MAGNETIZATION, *DENSITY gradient centrifugation, *THERMAL expansion, *MAGNETIC flux

Abstract

Two-dimensional hybrid simulations of super-Alfvénic expanding debris plasma interacting with an inhomogeneous ambient plasma are presented. The simulations demonstrate improved collisionless coupling of energy to the ambient ions when encountering a density gradient. Simulations of an expanding cylinder running into a step function gradient are performed and compared to a simple analytical theory. Magnetic flux probe data from a laboratory shock experiment are compared to a simulation with a more realistic debris expansion and ambient ion density. The simulation confirms that a shock is formed and propagates within the high density region of ambient plasma. [ABSTRACT FROM AUTHOR]

Published

2014