Your search keyword '"Cassak, Paul A."' showing total 31 results

1. First-principles theory of the rate of magnetic reconnection in magnetospheric and solar plasmas

Author

Liu, Yi-Hsin, Cassak, Paul, Li, Xiaocan, Hesse, Michael, Lin, Shan-Chang, and Genestreti, Kevin

Published

2022

2. Scale filtering analysis of kinetic reconnection and its associated turbulence.

Author

Adhikari, Subash, Yang, Yan, Matthaeus, William H., Cassak, Paul A., Parashar, Tulasi N., and Shay, Michael A.

Subjects

PLASMA turbulence, TURBULENCE, ENERGY transfer, ENERGY dissipation, MAGNETIC reconnection

Abstract

Previously, using an incompressible von Kármán–Howarth formalism, the behavior of cross-scale energy transfer in magnetic reconnection and turbulence was found to be essentially identical to each other, independent of an external magnetic (guide) field, in the inertial and energy-containing ranges [Adhikari et al., Phys. Plasmas 30, 082904 (2023)]. However, this description did not account for the energy transfer in the dissipation range for kinetic plasmas. In this Letter, we adopt a scale-filtering approach to investigate this previously unaccounted-for energy transfer channel in reconnection. Using kinetic particle-in-cell simulations of antiparallel and component reconnection, we show that the pressure–strain interaction becomes important at scales smaller than the ion inertial length, where the nonlinear energy transfer term drops off. Also, the presence of a guide field makes a significant difference in the morphology of the scale-filtered energy transfer. These results are consistent with kinetic turbulence simulations, suggesting that the pressure strain interaction is the dominant energy transfer channel between electron scales and ion scales. [ABSTRACT FROM AUTHOR]

Published

2024

3. The Importance of Heat Flux in Quasi-Parallel Collisionless Shocks

Author

Haggerty, Colby C., Caprioli, Damiano, Cassak, Paul A., Barbhuiya, M. Hasan, Wilson III, Lynn, and Turner, Drew

Subjects

Physics - Space Physics, Astrophysics - High Energy Astrophysical Phenomena, Physics - Plasma Physics

Abstract

Collisionless plasma shocks are a common feature of many space and astrophysical systems and are sources of high-energy particles and non-thermal emission, channeling as much as 20\% of the shock's energy into non-thermal particles. The generation and acceleration of these non-thermal particles have been extensively studied, however, how these particles feed back on the shock hydrodynamics has not been fully treated. This work presents the results of self-consistent hybrid particle-in-cell simulations that show the effect of self-generated non-thermal particle populations on the nature of collisionless, quasi-parallel shocks. They contribute to a significant heat flux density upstream of the shock. Non-thermal particles downstream of the shock leak into the upstream region, taking energy away from the shock. This increases the compression ratio, slows the shock down, and flattens the non-thermal population's spectral index for lower Mach number shocks. We incorporate this into a revised theory for the Rankine-Hugoniot jump conditions that include this effect and it shows excellent agreement with simulations. The results have the potential to explain discrepancies between predictions and observations in a wide range of systems, such as inaccuracies of predictions of arrival times of coronal mass ejections and the conflicting radio and x-ray observations of intracluster shocks. These effects will likely need to be included in fluid modeling to accurately predict shock evolution., Comment: 7 pages, 3 figures, a lot of appendix

Published

2023

4. Advancing Theory and Modeling Efforts in Heliophysics

Author

Guo, Fan, Antiochos, Spiro, Cassak, Paul, Chen, Bin, Chen, Xiaohang, Dong, Chuanfei, Downs, Cooper, Giacalone, Joe, Haggerty, Colby C., Ji, Hantao, Karpen, Judith, Klimchuk, James, Li, Wen, Li, Xiaocan, Oka, Mitsuo, Reeves, Katharine K., Swisdak, Marc, and Tu, Weichao

Subjects

Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, FOS: Physical sciences, Astrophysics - Instrumentation and Methods for Astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Solar and Stellar Astrophysics (astro-ph.SR), Space Physics (physics.space-ph), Physics - Plasma Physics

Abstract

Heliophysics theory and modeling build understanding from fundamental principles to motivate, interpret, and predict observations. Together with observational analysis, they constitute a comprehensive scientific program in heliophysics. As observations and data analysis become increasingly detailed, it is critical that theory and modeling develop more quantitative predictions and iterate with observations. Advanced theory and modeling can inspire and greatly improve the design of new instruments and increase their chance of success. In addition, in order to build physics-based space weather forecast models, it is important to keep developing and testing new theories, and maintaining constant communications with theory and modeling. Maintaining a sustainable effort in theory and modeling is critically important to heliophysics. We recommend that all funding agencies join forces and consider expanding current and creating new theory and modeling programs--especially, 1. NASA should restore the HTMS program to its original support level to meet the critical needs of heliophysics science; 2. a Strategic Research Model program needs to be created to support model development for next-generation basic research codes; 3. new programs must be created for addressing mission-critical theory and modeling needs; and 4. enhanced programs are urgently required for training the next generation of theorists and modelers., White paper submitted to Heliophysics 2024 Decadal Survey

Published

2022

5. Three‐Dimensional Magnetic Reconnection Spreading in Current Sheets of Non‐Uniform Thickness.

Author

Arencibia, Milton, Cassak, Paul A., Shay, Michael A., Qiu, Jiong, Petrinec, Steven M., and Liang, Haoming

Subjects

MAGNETIC reconnection, CURRENT sheets, SOLAR flares, COLLISIONLESS plasmas, KINETIC energy, AURORAS, EARTH (Planet)

Abstract

Magnetic reconnection in naturally occurring and laboratory settings often begins locally and elongates, or spreads, in the direction perpendicular to the plane of reconnection. Previous work has largely focused on current sheets with a uniform thickness, for which the predicted spreading speed for anti‐parallel reconnection is the local speed of the current carriers. We derive a scaling theory of three‐dimensional (3D) spreading of collisionless anti‐parallel reconnection in a current sheet with its thickness varying in the out‐of‐plane direction, both for spreading from a thinner to thicker region and a thicker to thinner region. We derive an expression for calculating the time it takes for spreading to occur for a current sheet with a given profile of its thickness. A key result is that when reconnection spreads from a thinner to a thicker region, the spreading speed in the thicker region is slower than both the Alfvén speed and the speed of the local current carriers by a factor of the ratio of thin to thick current sheet thicknesses. This is important because magnetospheric and solar observations have previously measured the spreading speed to be slower than previously predicted, so the present mechanism might explain this feature. We confirm the theory via a parametric study using 3D two‐fluid numerical simulations. We use the prediction to calculate the time scale for reconnection spreading in Earth's magnetotail during geomagnetic activity. The results are also potentially important for understanding reconnection spreading in solar flares and the dayside magnetopause of Earth and other planets. Plain Language Summary: Magnetic reconnection is fundamental process in plasmas that converts magnetic energy into kinetic and thermal energy and is known to mediate eruptive solar flares and geomagnetic substorms that create the northern lights. The x‐line where magnetic reconnection occurs can elongate or spread over time in the direction normal to the plane of reconnection, and this trait has been observed in the laboratory, Earth's magnetosphere, and is thought to be related to the elongation of chromospheric ribbons during solar flares. This study presents a scaling theory of the three‐dimensional (3D) spreading of anti‐parallel magnetic reconnection in current sheets with thickness varying in the out‐of‐plane direction. A key result is that when reconnection spreads from a thinner to a thicker region, the spreading speed in the thicker region is slower than expected. This is important because magnetospheric and solar observations have observed slower spreading speeds than previously predicted, so the present mechanism might explain this feature. We confirm the theory with 3D numerical simulations and use the prediction to calculate the time scale for reconnection spreading in Earth's magnetotail during geomagnetic activity. Key Points: We derive a theory of three‐dimensional spreading of collisionless anti‐parallel reconnection in current sheets with non‐uniform thicknessSpreading from a thinner to a thicker current sheet occurs slower than local electron and Alfvén speeds, a key prediction of the theoryWe apply the theory to reconnection spreading in Earth's magnetotail and discuss potential implications for solar flare ribbons [ABSTRACT FROM AUTHOR]

Published

2023

6. Scaling Theory of 3D Magnetic Reconnection Spreading

Author

Arencibia, Milton, Cassak, Paul A., Shay, Michael A., and Priest, Eric R.

Subjects

Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Physics::Plasma Physics, Physics::Space Physics, FOS: Physical sciences, Astrophysics::Solar and Stellar Astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Physics - Plasma Physics

Abstract

We develop a first-principles scaling theory of the spreading of three-dimensional (3D) magnetic reconnection of finite extent in the out of plane direction. This theory addresses systems with or without an out of plane (guide) magnetic field, and with or without Hall physics. The theory reproduces known spreading speeds and directions with and without guide fields, unifying previous knowledge in a single theory. New results include: (1) Reconnection spreads in a particular direction if an x-line is induced at the interface between reconnecting and non-reconnecting regions, which is controlled by the out of plane gradient of the electric field in the outflow direction. (2) The spreading mechanism for anti-parallel collisionless reconnection is convection, as is known, but for guide field reconnection it is magnetic field bending. We confirm the theory using 3D two-fluid and resistive-magnetohydrodynamics simulations. (3) The theory explains why anti-parallel reconnection in resistive-magnetohydrodynamics does not spread. (4) The simulation domain aspect ratio, associated with the free magnetic energy, influences whether reconnection spreads or convects with a fixed x-line length. (5) We perform a simulation initiating anti-parallel collisionless reconnection with a pressure pulse instead of a magnetic perturbation, finding spreading is unchanged rather than spreading at the magnetosonic speed as previously suggested. The results provide a theoretical framework for understanding spreading beyond systems studied here, and are important for applications including two-ribbon solar flares and reconnection in Earth's magnetosphere., Accepted in AIP Physics of Plasmas, appearing in Volume #: 28, Issue #: 8, Issue: 2021-08-02. Ref. POP21-AR-00492

Published

2021

7. Pressure–strain interaction. I. On compression, deformation, and implications for Pi-D.

Author

Cassak, Paul A. and Barbhuiya, M. Hasan

Subjects

*SHEAR (Mechanics), *DEFORMATIONS (Mechanics), *POWER density, *COLLISIONLESS plasmas, *ENERGY conversion, *PHYSICS

Abstract

The pressure–strain interaction describes the rate per unit volume that energy is converted between bulk flow and thermal energy in neutral fluids or plasmas. The term has been written as a sum of the pressure dilatation and the collisionless analog of viscous heating referred to as Pi − D , which isolates the power density due to compressible and incompressible effects, respectively. It has been shown that Pi − D can be negative, which makes its identification as collisionless viscous heating troubling. We argue that an alternate decomposition of pressure–strain interaction can be useful for interpreting the underlying physics. Since Pi − D contains both normal deformation and shear deformation, we propose grouping the normal deformation with the pressure dilatation to describe the power density due to converging/diverging flows, with the balance describing the power density purely due to shear deformation. We then develop a kinetic theory interpretation of compression, normal deformation, and shear deformation. We use the results to determine the physical mechanisms that can make Pi − D negative. We argue that both decompositions can be useful for the study of energy conversion in weakly collisional or collisionless fluids and plasmas, and implications are discussed. [ABSTRACT FROM AUTHOR]

Published

2022

8. Pressure–strain interaction. III. Particle-in-cell simulations of magnetic reconnection.

Author

Barbhuiya, M. Hasan and Cassak, Paul A.

Subjects

*MAGNETIC reconnection, *SHEAR flow, *COMPRESSIBLE flow, *COLLISIONAL plasma, *PLASMA turbulence, *INCOMPRESSIBLE flow, *PLASMA materials processing, *COLLISIONLESS plasmas

Abstract

How energy is converted into thermal energy in weakly collisional and collisionless plasma processes, such as magnetic reconnection and plasma turbulence, has recently been the subject of intense scrutiny. The pressure–strain interaction has emerged as an important piece, as it describes the rate of conversion between bulk flow and thermal energy density. In two companion studies, we presented an alternate decomposition of the pressure–strain interaction to isolate the effects of converging/diverging flow and flow shear instead of compressible and incompressible flow, and we derived the pressure–strain interaction in magnetic field-aligned coordinates. Here, we use these results to study pressure–strain interaction during two-dimensional anti-parallel magnetic reconnection. We perform particle-in-cell simulations and plot the decompositions in both Cartesian and magnetic field-aligned coordinates. We identify the mechanisms contributing to positive and negative pressure–strain interaction during reconnection. This study provides a roadmap for interpreting numerical and observational data of the pressure–strain interaction, which should be important for studies of reconnection, turbulence, and collisionless shocks. [ABSTRACT FROM AUTHOR]

Published

2022

9. Pressure–strain interaction. II. Decomposition in magnetic field-aligned coordinates.

Author

Cassak, Paul A., Barbhuiya, M. Hasan, and Weldon, H. Arthur

Subjects

*PLASMA turbulence, *COLLISIONLESS plasmas, *MAGNETIC reconnection, *PLASMA materials processing, *MAGNETIC fields, *ENERGY density

Abstract

In weakly collisional and collisionless magnetized plasmas, the pressure–strain interaction describes the rate of conversion between bulk flow and thermal energy density. In this study, we derive an analytical expression for the pressure–strain interaction in a coordinate system with an axis aligned with the local magnetic field. The result is eight groups of terms corresponding to different physical mechanisms that can contribute to the pressure–strain interaction. We provide a physical description of each term. The results are immediately of interest to weakly collisional and collisionless magnetized plasmas and the fundamental processes that happen therein, including magnetic reconnection, magnetized plasma turbulence, and collisionless shocks. The terms in the field-aligned coordinate decomposition are likely accessible to measurement with satellite observations. [ABSTRACT FROM AUTHOR]

Published

2022

10. Particle-in-cell simulation data for investigation of a nascent magnetic flux rope at Earth's dayside magnetopause

Author

Eriksson, Stefan, Souza, Vitor M., Cassak, Paul A., and Hoilijoki, Sanni

Abstract

Particle-in-cell (PIC) simulation data that used as inputmagnetic field and plasma parameters measured by instrumentation onboardthe THEMIS-A spacecraft when it traversed the Earth'sdayside magnetopause boundary on November 15, 2010. Such observational data contains a number of evidences thatsupport the interpretation that the spacecraft might have detected the early stage of amagnetic flux rope flanked by two reconnection X-lines. A dedicated 2-DPIC simulation of this event has been performed to provide context to the observations. Three files with simulation data have been uploaded, and they are discussed next. File 1:bz_80.0000.sav Itcontains most of the PIC simulation data presented in the study. It can be accessed by typing the command "restore,bz_80.0000.sav" in any IDL (Interactive Data Language) terminal. The simulated variablescontained in thisfile were acquired at thelast simulation time t = 80 \(\Omega_{ci}^{-1}\), where \(\Omega_{ci}\)is the ion cyclotron frequency, and they are detailed below. 1) x, y, and z components of: magnetic and electric fields, total current density, ion (proton)and electron current densities; 2) ion and electron number densities, and diagonal elements of bothion and electron pressure tensors; 3) two one-dimensional arrays, namely,"x" and "y", containing the simulation grid information, anda two-dimensional matrix denoted as "psi" which is themagnetic scalar potential. File 2: rv_traced_particles.sav It'salso been saved inIDL formatwith its contents being retrieved in the same way of File 1 above.It contains an "rv" variablewithboth thelocationand velocity information (x, y, and z components) of 12 representative particleswhichhad their trajectoriestraced withinthe simulation domain for the durationof the simulation. The simulation used 64,000 time steps, and the particles'trajectoryinformationwas stored at every 2 time steps, thus "rv" is an array with dimensions 12 x 6 x 32000, with 12 being the number of traced particles, 6 being, respectively, the x, y and z components of the particle's position (indexes 0, 1, and 2) and velocity (indexes 3, 4, and 5).These representative particlesbelong to counter-propagating ion beams found in three ion velocity distribution functions (VDFs) which weremeasuredat simulation time t = 80 \(\Omega_{ci}^{-1}\), and at particular locations in the simulation domain. File 3: VDFs.zip It has 4 (four) ".txt" files,each referring to one of the VDFs measured within the simulation domain. The textfiles have three columns each,with the left, middle and right columns containing, respectively, theionspeed parallel to the local magnetic field direction, the ion speed in the direction defined by B x (E x B), where B and E are the simulated magnetic and electric fields, respectively, and finally the particle weights which are used in the simulation to ensure a uniform average number of particles per grid cell at the initial time. With this data one can construct histograms and reproduce the four VDFs shown in the study, provided the histogramis smoothed out with a gaussian filter havingawidth of 0.25.

Published

2020

11. Electron-only reconnection and associated electron heating and acceleration in PHASMA.

Author

Shi, Peiyun, Srivastav, Prabhakar, Barbhuiya, M. Hasan, Cassak, Paul A., Scime, Earl E., Swisdak, M., Beatty, Cuyler, Gilbert, Tyler, John, Regis, Lazo, Matthew, Nirwan, Ripudaman Singh, Paul, Mitchell, Scime, Ethan E., Stevenson, Katey, and Steinberger, Thomas

Subjects

DISTRIBUTION (Probability theory), ELECTRON distribution, ELECTRONS, THOMSON scattering, ELECTRON temperature

Abstract

Using incoherent Thomson scattering, electron heating and acceleration at the electron velocity distribution function (EVDF) level are investigated during electron-only reconnection in the PHAse Space MApping (PHASMA) facility. Reconnection arises during the merger of two kink-free flux ropes. Both push and pull type reconnection occur in a single discharge. Electron heating is localized around the separatrix, and the electron temperature increases continuously along the separatrix with distance from the X-line. The local measured gain in enthalpy flux is up to 70% of the incoming Poynting flux. Notably, non-Maxwellian EVDFs comprised of a warm bulk population and a cold beam are directly measured during the electron-only reconnection. The electron beam velocity is comparable to, and scales with, electron Alfvén speed, revealing the signature of electron acceleration caused by electron-only reconnection. The observation of oppositely directed electron beams on either side of the X-point provides "smoking-gun" evidence of the occurrence of electron-only reconnection in PHASMA. 2D particle-in-cell simulations agree well with the laboratory measurements. The measured conversion of Poynting flux into electron enthalpy is consistent with recent observations of electron-only reconnection in the magnetosheath [Phan et al., Nature 557, 202 (2018)] at similar dimensionless parameters as in the experiments. The laboratory measurements go beyond the magnetosheath observations by directly resolving the electron temperature gain. [ABSTRACT FROM AUTHOR]

Published

2022

12. Determination of structural parameters for ferrocenecarboxaldehyde using Fourier transform microwave spectroscopy.

Author

Subramanian, Ranga, Karunatilaka, Chandana, Schock, Riley O., Drouin, Brian J., Cassak, Paul A., and Kukolich, Stephen G.

Subjects

FOURIER transform spectroscopy, MICROWAVE spectroscopy, ATOMS, DIPOLE moments, LEAST squares, PHYSICAL & theoretical chemistry

Abstract

Gas-phase structural parameters for ferrocenecarboxaldehyde have been determined using Fourier transform microwave spectroscopy. Rotational transitions due to a-, b-, and c-type dipole moments were measured. Eighteen rotational constants were determined by fitting the measured transitions of various isotopomers using a rigid rotor Hamiltonian with centrifugal distortion constants. Least-squares fit and Kraitchman analyses have been used to determine the gas-phase structural parameters and the atomic coordinates of the molecule using the rotational constants for various isotopomers. Structural parameters determined from the least-squares fit are the Fe–C bond lengths to the cyclopentadienyl rings, r(Fe–C)=2.047(4) Å, and the distance between the carbon atoms of the cyclopentadienyl rings, r(C–C)=1.430(2) Å and r(C1–C1′)=1.46(1) Å of ring carbon and aldehyde carbon atom. Structural parameters were also obtained using density-functional theory calculations, and these were quite helpful in resolving ambiguities in the structural fit analysis, and providing some fixed parameters for the structural analysis. The results of the least squares and the calculations indicate that the carbon atoms of the Cp groups for ferrocenecarboxaldehyde are in an eclipsed conformation in the ground vibrational state. [ABSTRACT FROM AUTHOR]

Published

2005

13. Decomposition of plasma kinetic entropy into position and velocity space and the use of kinetic entropy in particle-in-cell simulations.

Author

Liang, Haoming, Cassak, Paul A., Servidio, Sergio, Shay, Michael A., Drake, James F., Swisdak, Marc, Argall, Matt R., Dorelli, John C., Scime, Earl E., Matthaeus, William H., Roytershteyn, Vadim, and Delzanno, Gian Luca

Subjects

*ENTROPY, *PLASMA physics, *PLASMA turbulence, *COLLISIONLESS plasmas, *MAGNETIC reconnection, *VELOCITY, *TOPOLOGICAL entropy

Abstract

We describe a systematic development of kinetic entropy as a diagnostic in fully kinetic particle-in-cell (PIC) simulations and use it to interpret plasma physics processes in heliospheric, planetary, and astrophysical systems. First, we calculate kinetic entropy in two forms—the "combinatorial" form related to the logarithm of the number of microstates per macrostate and the "continuous" form related to flnf, where f is the particle distribution function. We discuss the advantages and disadvantages of each and discuss subtleties about implementing them in PIC codes. Using collisionless PIC simulations that are two-dimensional in position space and three-dimensional in velocity space, we verify the implementation of the kinetic entropy diagnostics and discuss how to optimize numerical parameters to ensure accurate results. We show the total kinetic entropy is conserved to three percent in an optimized simulation of antiparallel magnetic reconnection. Kinetic entropy can be decomposed into a sum of a position space entropy and a velocity space entropy, and we use this to investigate the nature of kinetic entropy transport during collisionless reconnection. We find the velocity space entropy of both electrons and ions increases in time due to plasma heating during magnetic reconnection, while the position space entropy decreases due to plasma compression. This project uses collisionless simulations, so it cannot address physical dissipation mechanisms; nonetheless, the infrastructure developed here should be useful for studies of collisional or weakly collisional heliospheric, planetary, and astrophysical systems. Beyond reconnection, the diagnostic is expected to be applicable to plasma turbulence and collisionless shocks. [ABSTRACT FROM AUTHOR]

Published

2019

14. Measurements of structural and quadruple coupling parameters for bromoferrocene using microwave...

Author

Drouin, Brian J., Lavaty, T. Greg, Cassak, Paul A., and Kukolich, Stephen G.

Subjects

FERROCENE, MICROWAVE spectroscopy

Abstract

Describes the measurement of structural and quadruple coupling parameters for bromoferrocene using microwave spectroscopy. Obtaining rotational constants and quadruple coupling tensors; Determination of the structural parameters for bromoferrocene; Values of the quadruple coupling parameters in the principal quadruple axis systems.

Published

1997

15. The reduction of magnetic reconnection outflow jets to sub-Alfvénic speeds.

Author

Haggerty, Colby C., Shay, Michael A., Chasapis, Alexandros, Phan, Tai D., Drake, James F., Malakit, Kittipat, Cassak, Paul A., and Kieokaew, Rungployphan

Subjects

MAGNETIC reconnection, COLLISIONLESS plasmas, PLASMA instabilities, TEMPERATURE, MAGNETIC fields, PLASMA physics

Abstract

The outflow velocity of jets produced by collisionless magnetic reconnection is shown to be reduced by the ion exhaust temperature in fully kinetic particle in cell simulations and in situ satellite observations. We derive a scaling relationship for the outflow velocity based on the upstream Alfvén speed and the parallel ion exhaust temperature, which is verified in kinetic simulations and observations. The outflow speed reduction is shown to be due to the firehose instability criterion, and so, for large enough guide fields, this effect is suppressed and the outflow speed reaches the upstream Alfvén speed based on the reconnecting component of the magnetic field. [ABSTRACT FROM AUTHOR]

Published

2018

16. Cavitons and spontaneous hot flow anomalies in a hybrid-Vlasov global magnetospheric simulation.

Author

Blanco-Cano, Xochitl, Battarbee, Markus, Turc, Lucile, Dimmock, Andrew P., Kilpua, Emilia K. J., Hoilijoki, Sanni, Ganse, Urs, Sibeck, David G., Cassak, Paul A., Fear, Robert C., Jarvinen, Riku, Juusola, Liisa, Pfau-Kempf, Yann, Vainio, Rami, and Palmroth, Minna

Subjects

MAGNETOSPHERE, SPACE vehicles, SOLAR wind, SIMULATION methods & models, PARTICLE size distribution

Abstract

In this paper we present the first identification of foreshock cavitons and the formation of spontaneous hot flow anomalies (SHFAs) with the Vlasiator global magnetospheric hybrid-Vlasov simulation code. In agreement with previous studies we show that cavitons evolve into SHFAs. In the presented run, this occurs very near the bow shock. We report on SHFAs surviving the shock crossing into the downstream region and show that the interaction of SHFAs with the bow shock can lead to the formation of a magnetosheath cavity, previously identified in observations and simulations. We report on the first identification of long-term local weakening and erosion of the bow shock, associated with a region of increased foreshock SHFA and caviton formation, and repeated shock crossings by them. We show that SHFAs are linked to an increase in suprathermal particle pitch-angle spreads. The realistic length scales in our simulation allow us to present a statistical study of global caviton and SHFA size distributions, and their comparable size distributions support the theory that SHFAs are formed from cavitons. Virtual spacecraft observations are shown to be in good agreement with observational studies. [ABSTRACT FROM AUTHOR]

Published

2018

17. Simulation and Analysis of Magnetic Reconnection in an Experimental Geometry

Author

Murphy, Nicholas A., Sovinec, Carl R., and Cassak, Paul

Subjects

Physics::Plasma Physics, magnetic reconnection, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics

Abstract

The process of magnetic reconnection is important in space, laboratory, and astrophysical plasmas. The Magnetic Reconnection Experiment (MRX) is designed to study controlled reconnection in collisional and marginally collisionless plasmas (Yamada et al. 1997). We present single and two-fluid simulations of MRX using the NIMROD extended MHD code (Sovinec et al. 2004). These simulations highlight the interrelationship between the small-scale physics of the reconnection layer and the global magnetic field geometry. The communication between small and large scales is dominated by pressure gradients that result from a pileup of reconnection outflow. Toroidicity leads to asymmetry in either the inflow direction or the outflow direction, depending on the experimental mode of operation. To explain effects observed during reconnection with asymmetry in the outflow direction, we present an extension of the Sweet-Parker model that takes into account asymmetric downstream pressure. This model is applicable to reconnection in coronal mass ejections, the Earth's magnetotail, and in circumstellar disks present in hot star winds. This research is supported by the NSF Center for Magnetic Self-Organization in Laboratory and Astrophysical Plasmas.

Published

2009

18. Magnetic reconnection with asymmetry in the outflow direction

Author

Nicholas Murphy, Sovinec, Carl, and Cassak, Paul

Subjects

Physics::Plasma Physics, magnetic reconnection, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics

Abstract

Magnetic reconnection with asymmetry in the outflow direction occurs in the Earth's magnetotail, spheromak merging experiments, coronal mass ejections, and astrophysical disks. We analyze the case of steady reconnection with asymmetric downstream pressure, using conservation of mass, momentum, and energy to derive the outflow velocities for both sides of the reconnection layer. As in reconnection with asymmetric inflow [1], the flow stagnation point and magnetic field null will not coincide, unless the pressure gradient is negligible at the flow stagnation point. When the two points are separated, there will be a Poynting flux across the flow stagnation point. We compare the derived properties of this model with resistive MHD simulations of driven reconnection. We perform a similar analysis for reconnection in toroidal geometry when the outflow is aligned with the radial direction. The toroidal geometry model is compared against simulations of push reconnection (similar to spheromak merging) using the geometry of the MRX device [2]. [1] P. A. Cassak & M. A. Shay, Phys. Plasmas 14, 102114 (2007) [2] N. A. Murphy & C. R. Sovinec, Phys. Plasmas 15, 042313 (2008)

Published

2008

19. Scaling the Ion Inertial Length and Its Implications for Modeling Reconnection in Global Simulations.

Author

Tóth, Gábor, Chen, Yuxi, Gombosi, Tamas I., Cassak, Paul, Markidis, Stefano, and Peng, Ivy Bo

Abstract

We investigate the use of artificially increased ion and electron kinetic scales in global plasma simulations. We argue that as long as the global and ion inertial scales remain well separated, (1) the overall global solution is not strongly sensitive to the value of the ion inertial scale, while (2) the ion inertial scale dynamics will also be similar to the original system, but it occurs at a larger spatial scale, and (3) structures at intermediate scales, such as magnetic islands, grow in a self-similar manner. To investigate the validity and limitations of our scaling hypotheses, we carry out many simulations of a two-dimensional magnetosphere with the magnetohydrodynamics with embedded particle-in-cell (MHD-EPIC) model. The PIC model covers the dayside reconnection site. The simulation results confirm that the hypotheses are true as long as the increased ion inertial length remains less than about 5% of the magnetopause standoff distance. Since the theoretical arguments are general, we expect these results to carry over to three dimensions. The computational cost is reduced by the third and fourth powers of the scaling factor in two- and three-dimensional simulations, respectively, which can be many orders of magnitude. The present results suggest that global simulations that resolve kinetic scales for reconnection are feasible. This is a crucial step for applications to the magnetospheres of Earth, Saturn, and Jupiter and to the solar corona. [ABSTRACT FROM AUTHOR]

Published

2017

20. Global Three-Dimensional Simulation of Earth's Dayside Reconnection Using a Two-Way Coupled Magnetohydrodynamics With Embedded Particle-in-Cell Model: Initial Results.

Author

Chen, Yuxi, Tóth, Gábor, Cassak, Paul, Jia, Xianzhe, Gombosi, Tamas I., Slavin, James A., Markidis, Stefano, Peng, Ivy Bo, Jordanova, Vania K., and Henderson, Michael G.

Abstract

We perform a three-dimensional (3-D) global simulation of Earth's magnetosphere with kinetic reconnection physics to study the flux transfer events (FTEs) and dayside magnetic reconnection with the recently developed magnetohydrodynamics with embedded particle-in-cell model. During the 1 h long simulation, the FTEs are generated quasi-periodically near the subsolar point and move toward the poles. We find that the magnetic field signature of FTEs at their early formation stage is similar to a 'crater FTE,' which is characterized by a magnetic field strength dip at the FTE center. After the FTE core field grows to a significant value, it becomes an FTE with typical flux rope structure. When an FTE moves across the cusp, reconnection between the FTE field lines and the cusp field lines can dissipate the FTE. The kinetic features are also captured by our model. A crescent electron phase space distribution is found near the reconnection site. A similar distribution is found for ions at the location where the Larmor electric field appears. The lower hybrid drift instability (LHDI) along the current sheet direction also arises at the interface of magnetosheath and magnetosphere plasma. The LHDI electric field is about 8 mV/m, and its dominant wavelength relative to the electron gyroradius agrees reasonably with Magnetospheric Multiscale (MMS) observations. [ABSTRACT FROM AUTHOR]

Published

2017

21. Reconnection rates and X line motion at the magnetopause: Global 2D-3V hybrid-Vlasov simulation results.

Author

Hoilijoki, Sanni, Ganse, Urs, Pfau-Kempf, Yann, Cassak, Paul A., Walsh, Brian M., Hietala, Heli, Alfthan, Sebastian, and Palmroth, Minna

Published

2017

22. Measurements of structural and quadrupolar coupling parameters for chloroferrocene using...

Author

Drouin, Brian J. and Cassak, Paul A.

Subjects

*FERROCENE, *SPECTRUM analysis

Abstract

Presents information on ferrocene and its derivatives, while focusing on a study which measured rotational spectra for two isotopomers of chloroferrocene using pulsed-beam Fourier transfrom microwave spectroscopy. Research methodology; Statistical data analysis; Results of this study.

Published

1997

23. Magnetic Reconnection at the Dayside Magnetopause Observed during Continuous IMF Rotation.

Author

Trattner, Karlheinz, Fuselier, Stephen, Petrinec, Steven, Burch, James, Cassak, Paul, Ergun, Robert, Giles, Barbara, Torbert, Roy, and Wilder, Frederick

Published

2019

24. Stationarity of the Reconnection X-Line at the Dayside Magnetopause.

Author

Fuselier, Stephen, Trattner, Karlheinz, Petrinec, Steven, Pritchard, Kristina, Burch, James, Cassak, Paul, Giles, Barbara, and Strangeway, Robert

Published

2019

25. MMS Multi-Point Analysis of FTEs: Stress Balance, Plasma Energization, and Instabilities.

Author

Akhavan-Tafti, Mojtaba, Slavin, James A., Eastwood, Jonathan P., Cassak, Paul, and Gershman, Daniel J.

Published

2018

26. Cassak, Ehlmann, Heald, Jackson, and Maher Receive 2015 James B. Macelwane Medals.

Author

Burch, James L. and Cassak, Paul

Published

2016

27. Laboratory Observations of Electron Heating and Non-Maxwellian Distributions at the Kinetic Scale during Electron-Only Magnetic Reconnection.

Author

Peiyun Shi, Srivastav, Prabhakar, Barbhuiya, M. Hasan, Cassak, Paul A., Scime, Earl E., and Swisdak, M.

Subjects

*MAGNETIC reconnection, *ELECTRON distribution, *ELECTRONS, *ELECTRON temperature, *MAGNETIC nanoparticle hyperthermia, *ELECTRON beams

Abstract

Non-Maxwellian electron velocity distribution functions composed of a warm bulk population and a cold beam are directly measured during electron-only reconnection with a strong out-of-plane (guide) magnetic field in a laboratory plasma. Electron heating is localized to the separatrix, and the electron temperature increases continuously along the separatrix. The measured gain in enthalpy flux is 70% of the incoming Poynting flux. The electron beams are oppositely directed on either side of the X point, and their velocities are comparable to, and scale with, the electron Alfvén speed. Particle-in-cell simulations are consistent with the measurements. The experimental results are consistent with, and go beyond, recent observations in the magnetosheath. [ABSTRACT FROM AUTHOR]

Published

2022

28. Higher-order nonequilibrium term: Effective power density quantifying evolution towards or away from local thermodynamic equilibrium.

Author

Barbhuiya MH, Cassak PA, Adhikari S, Parashar TN, Liang H, and Argall MR

Abstract

A common approach to assess the nature of energy conversion in a classical fluid or plasma is to compare power densities of the various possible energy conversion mechanisms. A leading research area is quantifying energy conversion for systems that are not in local thermodynamic equilibrium (LTE), as is common in a number of fluid and plasma systems. Here we introduce the "higher-order nonequilibrium term" (HORNET) effective power density, which quantifies the rate of change of departure of a phase space density from LTE. It has dimensions of power density, which allows for quantitative comparisons with standard power densities. We employ particle-in-cell simulations to calculate HORNET during two processes, magnetic reconnection and decaying kinetic turbulence in collisionless magnetized plasmas, that inherently produce non-LTE effects. We investigate the spatial variation of HORNET and the time evolution of its spatial average. By comparing HORNET with power densities describing changes to the internal energy (pressure dilatation, Pi-D, and divergence of the vector heat flux density), we find that HORNET can be a significant fraction of these other measures (8% and 35% for electrons and ions, respectively, for reconnection; up to 67% for both electrons and ions for turbulence), meaning evolution of the system towards or away from LTE can be dynamically important. Applications to numerous plasma phenomena are discussed.

Published

2024

29. Using Direct Laboratory Measurements of Electron Temperature Anisotropy to Identify the Heating Mechanism in Electron-Only Guide Field Magnetic Reconnection.

Author

Shi P, Scime EE, Barbhuiya MH, Cassak PA, Adhikari S, Swisdak M, and Stawarz JE

Abstract

Anisotropic electron heating during electron-only magnetic reconnection with a large guide magnetic field is directly measured in a laboratory plasma through in situ measurements of electron velocity distribution functions. Electron heating preferentially parallel to the magnetic field is localized to one separatrix, and anisotropies of 1.5 are measured. The mechanism for electron energization is identified as the parallel reconnection electric field because of the anisotropic nature of the heating and spatial localization. These characteristics are reproduced in a 2D particle-in-cell simulation and are also consistent with numerous magnetosheath observations. A measured increase in the perpendicular temperature along both separatrices is not reproduced by our 2D simulations. This work has implications for energy partition studies in magnetosheath and laboratory reconnection.

Published

2023

30. Quantifying Energy Conversion in Higher-Order Phase Space Density Moments in Plasmas.

Author

Cassak PA, Barbhuiya MH, Liang H, and Argall MR

Abstract

Weakly collisional and collisionless plasmas are typically far from local thermodynamic equilibrium (LTE), and understanding energy conversion in such systems is a forefront research problem. The standard approach is to investigate changes in internal (thermal) energy and density, but this omits energy conversion that changes any higher-order moments of the phase space density. In this Letter, we calculate from first principles the energy conversion associated with all higher moments of the phase space density for systems not in LTE. Particle-in-cell simulations of collisionless magnetic reconnection reveal that energy conversion associated with higher-order moments can be locally significant. The results may be useful in numerous plasma settings, such as reconnection, turbulence, shocks, and wave-particle interactions in heliospheric, planetary, and astrophysical plasmas.

Published

2023

31. Laboratory Observations of Electron Heating and Non-Maxwellian Distributions at the Kinetic Scale during Electron-Only Magnetic Reconnection.

Author

Shi P, Srivastav P, Barbhuiya MH, Cassak PA, Scime EE, and Swisdak M

Abstract

Non-Maxwellian electron velocity distribution functions composed of a warm bulk population and a cold beam are directly measured during electron-only reconnection with a strong out-of-plane (guide) magnetic field in a laboratory plasma. Electron heating is localized to the separatrix, and the electron temperature increases continuously along the separatrix. The measured gain in enthalpy flux is 70% of the incoming Poynting flux. The electron beams are oppositely directed on either side of the X point, and their velocities are comparable to, and scale with, the electron Alfvén speed. Particle-in-cell simulations are consistent with the measurements. The experimental results are consistent with, and go beyond, recent observations in the magnetosheath.

Published

2022