Your search keyword '"Vyacheslav S. Lukin"' showing total 20 results

1. Two-fluid simulations of Rayleigh-Taylor instability in a magnetized solar prominence thread. I. Effects of prominence magnetization and mass loading

Author

Elena Khomenko, B. Popescu Braileanu, Vyacheslav S. Lukin, and A. de Vicente

Subjects

atmosphere [Sun], FOS: Physical sciences, Astrophysics, Astronomy & Astrophysics, 01 natural sciences, Instability, Computer Science::Digital Libraries, Solar prominence, 010305 fluids & plasmas, Ionization, 0103 physical sciences, Rayleigh–Taylor instability, Magnetohydrodynamic drive, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Physics, Science & Technology, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy and Astrophysics, Plasma, Mechanics, Charged particle, Physics::History of Physics, Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, instabilities, Physical Sciences

Abstract

Solar prominences are formed by partially ionized plasma with inter-particle collision frequencies, which generally warrant magnetohydrodynamic treatment. In this work, we explore the dynamical impacts and observable signatures of two-fluid effects in the parameter regimes when ion-neutral collisions do not fully couple the neutral and charged fluids. We performed 2.5D two-fluid (charge – neutrals) simulations of the Rayleigh-Taylor instability (RTI) at a smoothly changing interface between a solar prominence thread and the corona. The purpose of this study is to deepen our understanding of the RTI and the effects of partial ionization on the development of the RTI using nonlinear two-fluid numerical simulations. Our two-fluid model takes into account viscosity, thermal conductivity, and collisional interaction between neutrals and charge: ionization or recombination, energy and momentum transfer, and frictional heating. In this paper, we explore the sensitivity of the RTI dynamics to the prominence equilibrium configuration, including the impact of the magnetic field strength and shear supporting the prominence thread, and the amount of prominence mass-loading. We show that at small scales, a realistically smooth prominence-corona interface leads to qualitatively different linear RTI evolution than that which is expected for a discontinuous interface, while magnetic field shear has the stabilizing effect of reducing the growth rate or eliminating the instability. In the nonlinear phase, we observe that in the presence of field shear the development of the instability leads to formation of coherent and interacting 2.5D magnetic structures, which, in turn, can lead to substantial plasma flow across magnetic field lines and associated decoupling of the fluid velocities of charged particles and neutrals.

Published

2020

2. Two-fluid simulations of Rayleigh-Taylor instability in a magnetized solar prominence thread

Author

A. de Vicente, Vyacheslav S. Lukin, B. Popescu Braileanu, and Elena Khomenko

Subjects

Physics, Inelastic collision, FOS: Physical sciences, Astronomy and Astrophysics, Mechanics, Astrophysics, Collisionality, 01 natural sciences, Instability, Physics - Plasma Physics, Solar prominence, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Collision frequency, Space and Planetary Science, Ionization, 0103 physical sciences, Rayleigh–Taylor instability, 010306 general physics, Neutral particle, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Solar prominences are formed by partially ionized plasma with inter-particle collision frequencies generally warranting magnetohydrodynamic treatment. In this work we explore the dynamical impacts and observable signatures of two-fluid effects in the parameter regimes when ion-neutral collisions do not fully couple the neutral and charged fluids. We perform 2.5D two-fluid (charges-neutrals) simulations of the Rayleigh-Taylor instability (RTI) at a smoothly changing interface between a solar prominence thread and the corona. The purpose of this study is to deepen our understanding of the RTI and the effects of the partial ionization on the development of RTI using nonlinear two-fluid numerical simulations. Our two-fluid model takes into account neutral viscosity, thermal conductivity, and collisional interaction between neutrals and charges: ionization–recombination, energy and momentum transfer, and frictional heating. In this paper, the sensitivity of the RTI dynamics to collisional effects for different magnetic field configurations supporting the prominence thread is explored. This is done by artificially varying, or eliminating, effects of both elastic and inelastic collisions by modifying the model equations. We find that ionization and recombination reactions between ionized and neutral fluids do not substantially impact the development of the primary RTI. However, such reactions can impact the development of secondary structures during the mixing of the cold prominence and hotter surrounding coronal material. We find that collisionality within and between ionized and neutral particle populations plays an important role in both linear and nonlinear development of RTI; ion-neutral collision frequency is the primary determining factor in development or damping of small-scale structures. We also observe that the degree and signatures of flow decoupling between ion and neutral fluids can depend on the inter-particle collisionality and on the magnetic field configuration of the prominence thread.

Published

2021

3. Two-fluid simulations of waves in the solar chromosphere I: numerical code verification

Author

Elena Khomenko, B. Popescu Braileanu, Vyacheslav S. Lukin, and A. de Vicente

Subjects

FOS: Physical sciences, Astrophysics, 01 natural sciences, 010305 fluids & plasmas, Alfvén wave, Collision frequency, Physics - Space Physics, Speed of sound, 0103 physical sciences, 010303 astronomy & astrophysics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR), Physics, Momentum transfer, Astronomy and Astrophysics, Mechanics, Acoustic wave, Computational Physics (physics.comp-ph), Space Physics (physics.space-ph), Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Physics::Space Physics, Induction equation, Physics - Computational Physics, Numerical stability

Abstract

Solar chromosphere consists of a partially ionized plasma, which makes modeling the solar chromosphere a particularly challenging numerical task. Here we numerically model chromospheric waves using a two-fluid approach with a newly developed numerical code. The code solves two-fluid equations of conservation of mass, momentum, and energy, together with the induction equation for the case of the purely hydrogen plasma with collisional coupling between the charged and neutral fluid components. The implementation of a semi-implicit algorithm allows us to overcome the numerical stability constraints due to the stiff collisional terms. We test the code against analytical solutions of acoustic and Alfvén wave propagation in uniform medium in several regimes of collisional coupling. The results of our simulations are consistent with the analytical estimates, and with other results described in the literature. In the limit of a large collisional frequency, the waves propagate with a common speed of a single fluid. In the other limit of a vanishingly small collisional frequency, the Alfvén waves propagate with an Alfvén speed of the charged fluid only, while the perturbation in neutral fluid is very small. The acoustic waves in these limits propagate with the sound speed corresponding to either the charges or the neutrals, while the perturbation in the other fluid component is negligible. Otherwise, when the collision frequency is similar to the real part of the wave frequency, the interaction between charges and neutrals through momentum-transfer collisions cause alterations of the waves frequencies and damping of the wave amplitudes.

Published

2019

4. Onset of secondary instabilities and plasma heating during magnetic reconnection in strongly magnetized regions of the low solar atmosphere

Author

Vyacheslav S. Lukin and Lei Ni

Subjects

FOS: Physical sciences, Plasmoid, 01 natural sciences, 010305 fluids & plasmas, Current sheet, Physics - Space Physics, Physics::Plasma Physics, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR), Physics, Astronomy and Astrophysics, Magnetic reconnection, Plasma, Space Physics (physics.space-ph), Physics - Plasma Physics, Computational physics, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Beta (plasma physics), Physics::Space Physics, Plasma parameter, Lundquist number

Abstract

We numerically study magnetic reconnection on different spatial scales and at different heights in the weakly ionized plasma of the low solar atmosphere (around $300-800$~km above the solar surface) within a reactive 2.5 D multi-fluid plasma-neutral model. We consider a strongly magnetized plasma ($\beta \sim 6\% $) evolving from a force-free magnetic configuration and perturbed to initialize formation of a reconnection current sheet. On large scales, the resulting current sheets are observed to undergo a secondary 'plasmoid' instability. A series of simulations at different scales demonstrate a cascading current sheet formation process that terminates for current sheets with width of ~2m and length of $\sim100$~m, corresponding to the critical current sheet aspect ratio of $\sim50$. We also observe that the plasmoid instability is the primary physical mechanism accelerating the magnetic reconnection in this plasma parameter regime. After plasmoid instabilities appear, the reconnection rate sharply increases to a value of $\sim$ 0.035, observed to be independent of the Lundquist number. These characteristics are very similar to magnetic reconnection in fully ionized plasmas. In this low $\beta$ guide field reconnection regime, both the recombination and collisionless effects are observed to have a small contribution to the reconnection rate. The simulations show that it is difficult to heat the dense weakly ionized photospheric plasmas to above $2\times10^4$~K during the magnetic reconnection process. However, the plasmas in the low solar chromosphere can be heated above $3\times10^4$~K with reconnection magnetic fields of $500$~G or stronger.

Published

2018

5. Reflection of fast magnetosonic waves near magnetic reconnection region

Author

J. M. Laming, E. Provornikova, and Vyacheslav S. Lukin

Subjects

FOS: Physical sciences, Plasmoid, 01 natural sciences, Article, Current sheet, Physics - Space Physics, Physics::Plasma Physics, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, 010306 general physics, 010303 astronomy & astrophysics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR), Physics, Astronomy and Astrophysics, Magnetic reconnection, Ponderomotive force, Space Physics (physics.space-ph), Physics - Plasma Physics, Computational physics, Plasma Physics (physics.plasm-ph), Wavelength, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Physics::Space Physics, Reflection (physics), Magnetohydrodynamics

Abstract

Magnetic reconnection in the solar corona is thought to be unstable to the formation of multiple interacting plasmoids, and previous studies have shown that plasmoid dynamics can trigger MHD waves of different modes propagating outward from the reconnection site. However, variations in plasma parameters and magnetic field strength in the vicinity of a coronal reconnection site may lead to wave reflection and mode conversion. In this paper we investigate the reflection and refraction of fast magnetoacoustic waves near a reconnection site. Under a justified assumption of an analytically specified Alfv\'{e}n speed profile, we derive and solve analytically the full wave equation governing propagation of fast mode waves in a non-uniform background plasma without recourse to the small-wavelength approximation. We show that the waves undergo reflection near the reconnection current sheet due to the Alfv\'en speed gradient and that the reflection efficiently depends on the plasma-$\beta$ parameter as well as on the wave frequency. In particular, we find that waves are reflected more efficiently near reconnection sites in a low-$\beta$ plasma which is typical for the solar coronal conditions. Also, the reflection is larger for lower frequency waves while high frequency waves propagate outward from the reconnection region almost without the reflection. We discuss the implications of efficient wave reflection near magnetic reconnection sites in strongly magnetized coronal plasma for particle acceleration, and also the effect this might have on First Ionization Potential (FIP) fractionation by the ponderomotive force of these waves in the chromosphere., Comment: 28 pages, 10 figures, submitted to the Astrophysical Journal

Published

2018

6. Magnetic reconnection in strongly magnetized regions of the low solar chromosphere

Author

Jun Lin, Lei Ni, Nicholas A. Murphy, and Vyacheslav S. Lukin

Subjects

FOS: Physical sciences, 01 natural sciences, 010305 fluids & plasmas, Current sheet, Physics - Space Physics, Physics::Plasma Physics, 0103 physical sciences, 010303 astronomy & astrophysics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR), Physics, Magnetic energy, Astronomy and Astrophysics, Magnetic reconnection, Plasma, Space Physics (physics.space-ph), Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Beta (plasma physics), Physics::Space Physics, Atomic physics, Magnetohydrodynamics, human activities

Abstract

Magnetic reconnection in strongly magnetized regions around the temperature minimum region of the low solar atmosphere is studied by employing MHD-based simulations of a partially ionized plasma within a reactive 2.5D multi-fluid model. It is shown that in the absence of magnetic nulls in a low $\beta$ plasma the ionized and neutral fluid flows are well-coupled throughout the reconnection region. However, non-equilibrium ionization-recombination dynamics play a critical role in determining the structure of the reconnection region, lead to much lower temperature increases and a faster magnetic reconnection rate as compared to simulations that assume plasma to be in ionization-recombination equilibrium. The rate of ionization of the neutral component of the plasma is always faster than recombination within the current sheet region even when the initial plasma $\beta$ is as high as $\beta_0=1.46$. When the reconnecting magnetic field is in excess of a kilogauss and the plasma $\beta$ is lower than 0.0145, the initially weakly ionized plasmas can become fully ionized within the reconnection region and the current sheet can be strongly heated to above $2.5\times10^4$~K, even as most of the collisionally dissipated magnetic energy is radiated away. The Hall effect increases the reconnection rate slightly, but in the absence of magnetic nulls it does not result in significant asymmetries or change the characteristics of the reconnection current sheet down to meter scales.

Published

2017

7. Two-fluid simulations of waves in the solar chromosphere

Author

B. Popescu Braileanu, Vyacheslav S. Lukin, A. de Vicente, and Elena Khomenko

Subjects

Physics, Shock wave, Photosphere, 010308 nuclear & particles physics, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, Acoustic wave, Decoupling (cosmology), Plasma, 01 natural sciences, Computational physics, Magnetic field, Amplitude, Astrophysics - Solar and Stellar Astrophysics, 13. Climate action, Space and Planetary Science, Physics::Space Physics, 0103 physical sciences, 010303 astronomy & astrophysics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Waves and shocks traveling through the solar chromospheric plasma are influenced by its partial ionization and weak collisional coupling, and may become susceptible to multi-fluid effects, similar to interstellar shock waves. In this study, we consider fast magneto-acoustic shock wave formation and propagation in a stratified medium, that is permeated by a horizontal magnetic field, with properties similar to that of the solar chromosphere. The evolution of plasma and neutrals is modeled using a two-fluid code that evolves a set of coupled equations for two separate fluids. We observed that waves in neutrals and plasma, initially coupled at the upper photosphere, become uncoupled at higher heights in the chromosphere. This decoupling can be a consequence of either the characteristic spatial scale at the shock front, that becomes similar to the collisional scale, or the change in the relation between the wave frequency, ion cyclotron frequency, and the collisional frequency with height. The decoupling height is a sensitive function of the wave frequency, wave amplitude, and the magnetic field strength. We observed that decoupling causes damping of waves and an increase in the background temperature due to the frictional heating. The comparison between analytical and numerical results allows us to separate the role of the nonlinear effects from the linear ones on the decoupling and damping of waves.

Published

2019

8. Overview of recent physics results from MAST

Author

A. Kirk, J. Horacek, C. D. Challis, I. Klimek, W. A. Peebles, K. Imada, W. A. Gracias, H. R. Wilson, A. W. Morris, L. Piron, K Tani, M. Wischmeier, Sean Conroy, D. A. Ryan, M. O’Brien, F. Arese Lucini, Fabio Riva, Ryota Imazawa, Sandra C. Chapman, Anders Nielsen, P. Cahyna, Nick Walkden, Michael Barnes, I. Fitzgerald, C. Gurl, G. Fishpool, A. Patel, Takuma Yamada, M. Cecconello, M. Turnyanskiy, Ben F. McMillan, A. R. Field, G. Cunningham, Y. Liu, T.R. Barrett, F. J. Casson, Michael F. J. Fox, M. Cox, G. Naylor, A.J. Thornton, Matthew Carr, Nicolas Fedorczak, R. Scannell, L. Pangione, L. Garzotti, N. C. Hawkes, Hiroshi Tanabe, T. Farley, Yasushi Ono, M. Evans, Gen Motojima, Daniel Dunai, T. O'Gorman, S. Saarelma, William Dorland, H. F. Meyer, G. McArdle, B. Huang, E. Havlickova, T. Watanabe, Michiaki Inomoto, R. O. Dendy, Paolo Ricci, Edmund Highcock, F. van Wyk, H. Leggate, Matthias Komm, Jens Madsen, Alexander Schekochihin, S. A. Silburn, I. T. Chapman, S.M. Kaye, Hajime Tanaka, Jeppe Olsen, F. Militello, S. D. Pinches, R. V. Perez, D. Harting, K. G. McClements, Jarrod Leddy, C. M. Roach, Roddy G. L. Vann, Luke Easy, Walter Guttenfelder, Patrick Tamain, Benjamin Daniel Dudson, M. G. O'Mullane, John Omotani, W. A. Cooper, B. Lloyd, Felix I. Parra, K. J. Gibson, EUROfusion Mst Team, S. Cardnell, N. J. Conway, O. M. Jones, W. Lai, J. Young, S. S. Henderson, Brendan M. Crowley, Romualdo Martín, Neal Crocker, A. Meakins, A. V. Danilov, Ray M. Sharples, D. L. Keeling, M. Gorelenkova, J. Simpson, J. Hollocombe, J. Adamek, Bogdan Hnat, N. Ben Ayed, L Kogan, Matthew Reinke, M. Valovic, J. R. Harrison, Bruce Lipschultz, Vladimir Shevchenko, Clive Michael, J. Storrs, M. Romanelli, M. Price, S. E. Sharapov, John Howard, J. Mailloux, N. Thomas-Davies, D. Muir, Stanislas Pamela, David Dickinson, James W. Bradley, M. Kocan, J. Chorley, Philippa Browning, H. P. Summers, Yuichi Takase, Vyacheslav S. Lukin, G. P. Maddison, J. Milnes, Keii Gi, L. Appel, Adam Stanier, Daniel Thomas, S. Allan, Ivan Lupelli, Young-chul Ghim, D. F. Howell, J. C. Hillesheim, S.W. Lisgo, A. N. Saveliev, David Taylor, W. Boeglin, Kazutake Kadowaki, J. Brunner, C. Ham, R. J. Akers, D. S. Darrow, B. Lomanowski, T. C. Hender, S. Elmore, Mast Team, Simon Freethy, S. Zoletnik, Kouji Shinohara, MAST Team, and EUROfusion MST1 Team

Subjects

Physics, Nuclear and High Energy Physics, Toroid, Turbulence, Divertor, FOS: Physical sciences, Electron, Plasma, Condensed Matter Physics, 7. Clean energy, 01 natural sciences, Resonant magnetic perturbations, Physics - Plasma Physics, 010305 fluids & plasmas, Computational physics, Plasma Physics (physics.plasm-ph), Pedestal, Physics::Plasma Physics, 0103 physical sciences, Electron temperature, 010306 general physics

Abstract

New results from MAST are presented that focus on validating models in order to extrapolate to future devices. Measurements during start-up experiments have shown how the bulk ion temperature rise scales with the square of the reconnecting field. During the current ramp up models are not able to correctly predict the current diffusion. Experiments have been performed looking at edge and core turbulence. At the edge detailed studies have revealed how filament characteristic are responsible for determining the near and far SOL density profiles. In the core the intrinsic rotation and electron scale turbulence have been measured. The role that the fast ion gradient has on redistributing fast ions through fishbone modes has led to a redesign of the neutral beam injector on MAST Upgrade. In H-mode the turbulence at the pedestal top has been shown to be consistent with being due to electron temperature gradient modes. A reconnection process appears to occur during ELMs and the number of filaments released determines the power profile at the divertor. Resonant magnetic perturbations can mitigate ELMs provided the edge peeling response is maximised and the core kink response minimised. The mitigation of intrinsic error fields with toroidal mode number n>1 has been shown to be important for plasma performance., 34 pages, 10 figures. This is an author-created, un-copyedited version of an article submitted for publication in Nuclear Fusion. IoP Publishing Ltd is not responsible for any errors or omissions in this version of the manuscript or any version derived from it

Published

2016

9. A Two-Fluid Study of Oblique Tearing Modes in a Force-Free Current Sheet

Author

William Daughton, Cihan Akcay, Vyacheslav S. Lukin, and Yi-Hsin Liu

Subjects

Physics, Field (physics), Oblique case, FOS: Physical sciences, Mechanics, Condensed Matter Physics, Kinetic energy, 01 natural sciences, Instability, Magnetic flux, Physics - Plasma Physics, 010305 fluids & plasmas, Plasma Physics (physics.plasm-ph), Current sheet, Physics::Plasma Physics, 0103 physical sciences, Tearing, Physics::Space Physics, Kinetic theory of gases, 010306 general physics

Abstract

Kinetic simulations have demonstrated that three-dimensional reconnection in collisionless regimes proceeds through the formation and interaction of magnetic flux ropes, which are generated due to the growth of tearing instabilities at multiple resonance surfaces. Since kinetic simulations are intrinsically expensive, it is desirable to explore the feasibility of reduced two-fluid models to capture this complex evolution, particularly, in the strong guide field regime, where two-fluid models are better justified. With this goal in mind, this paper compares the evolution of the collisionless tearing instability in a force-free current sheet with a two-fluid model and fully kinetic simulations. Our results indicate that the most unstable modes are oblique for guide fields larger than the reconnecting field, in agreement with the kinetic results. The standard two-fluid tearing theory is extended to address the tearing instability at oblique angles. The resulting theory yields a flat oblique spectrum and underestimates the growth of oblique modes in a similar manner to kinetic theory relative to kinetic simulations., accepted for publication in Physics of plasmas (February or March 2016 issue)

Published

2016

10. Magnetic reconnection in the low solar chromosphere with a more realistic radiative cooling model

Author

Nicholas A. Murphy, Vyacheslav S. Lukin, Jun Lin, and Lei Ni

Subjects

Physics, Radiative cooling, Ambipolar diffusion, FOS: Physical sciences, Magnetic reconnection, Plasma, Condensed Matter Physics, 01 natural sciences, Computational physics, Current sheet, Astrophysics - Solar and Stellar Astrophysics, Physics::Plasma Physics, Ionization, Physics::Space Physics, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Astrophysical plasma, 010306 general physics, 010303 astronomy & astrophysics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Magnetic reconnection is the most likely mechanism responsible for the high temperature events that are observed in strongly magnetized locations around the temperature minimum in the low solar chromosphere. This work improves upon our previous work [Ni et al., Astrophys. J. 852, 95 (2018)] by using a more realistic radiative cooling model computed from the OPACITY project and the CHIANTI database. We find that the rate of ionization of the neutral component of the plasma is still faster than recombination within the current sheet region. For low β plasmas, the ionized and neutral fluid flows are well-coupled throughout the reconnection region resembling the single-fluid Sweet-Parker model dynamics. Decoupling of the ion and neutral inflows appears in the higher β case with β0=1.46, which leads to a reconnection rate about three times faster than the rate predicted by the Sweet-Parker model. In all cases, the plasma temperature increases with time inside the current sheet, and the maximum value is above 2×104 K when the reconnection magnetic field strength is greater than 500 G. While the more realistic radiative cooling model does not result in qualitative changes of the characteristics of magnetic reconnection, it is necessary for studying the variations of the plasma temperature and ionization fraction inside current sheets in strongly magnetized regions of the low solar atmosphere. It is also important for studying energy conversion during the magnetic reconnection process when the hydrogen-dominated plasma approaches full ionization.Magnetic reconnection is the most likely mechanism responsible for the high temperature events that are observed in strongly magnetized locations around the temperature minimum in the low solar chromosphere. This work improves upon our previous work [Ni et al., Astrophys. J. 852, 95 (2018)] by using a more realistic radiative cooling model computed from the OPACITY project and the CHIANTI database. We find that the rate of ionization of the neutral component of the plasma is still faster than recombination within the current sheet region. For low β plasmas, the ionized and neutral fluid flows are well-coupled throughout the reconnection region resembling the single-fluid Sweet-Parker model dynamics. Decoupling of the ion and neutral inflows appears in the higher β case with β0=1.46, which leads to a reconnection rate about three times faster than the rate predicted by the Sweet-Parker model. In all cases, the plasma temperature increases with time inside the current sheet, and the maximum value is above ...

Published

2018

11. Asymmetric Magnetic Reconnection in Weakly Ionized Chromospheric Plasmas

Author

Vyacheslav S. Lukin and Nicholas A. Murphy

Subjects

Physics, FOS: Physical sciences, Astronomy and Astrophysics, Plasmoid, Magnetic reconnection, Plasma, Magnetic flux, Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), Current sheet, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Hall effect, Physics::Plasma Physics, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Atomic physics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Realistic models of magnetic reconnection in the solar chromosphere must take into account that the plasma is partially ionized and that plasma conditions within any two magnetic flux bundles undergoing reconnection may not be the same. Asymmetric reconnection in the chromosphere may occur when newly emerged flux interacts with pre-existing, overlying flux. We present 2.5D simulations of asymmetric reconnection in weakly ionized, reacting plasmas where the magnetic field strengths, ion and neutral densities, and temperatures are different in each upstream region. The plasma and neutral components are evolved separately to allow non-equilibrium ionization. As in previous simulations of chromospheric reconnection, the current sheet thins to the scale of the neutral-ion mean free path and the ion and neutral outflows are strongly coupled. However, the ion and neutral inflows are asymmetrically decoupled. In cases with magnetic asymmetry, a net flow of neutrals through the current sheet from the weak field (high density) upstream region into the strong field upstream region results from a neutral pressure gradient. Consequently, neutrals dragged along with the outflow are more likely to originate from the weak field region. The Hall effect leads to the development of a characteristic quadrupole magnetic field modified by asymmetry, but the X-point geometry expected during Hall reconnection does not occur. All simulations show the development of plasmoids after an initial laminar phase., Accepted for publication in the Astrophysical Journal

Published

2015

12. Two-fluid and magnetohydrodynamic modelling of magnetic reconnection in the MAST spherical tokamak and the solar corona

Author

Vyacheslav S. Lukin, Adam Stanier, Philippa Browning, M. Evans, S. Cardnell, K. G. McClements, and F. Arese Lucini

Subjects

Physics, Tokamak, Magnetic energy, FOS: Physical sciences, Magnetic reconnection, Plasma, Spherical tokamak, Condensed Matter Physics, 01 natural sciences, Magnetic flux, Physics - Plasma Physics, 010305 fluids & plasmas, Computational physics, Magnetic field, law.invention, Plasma Physics (physics.plasm-ph), Current sheet, Nuclear Energy and Engineering, law, Physics::Plasma Physics, 0103 physical sciences, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics

Abstract

Twisted magnetic flux ropes are ubiquitous in laboratory and astrophysical plasmas, and the merging of such flux ropes through magnetic reconnection is an important mechanism for restructuring magnetic fields and releasing free magnetic energy. The merging-compression scenario is one possible start-up scheme for spherical tokamaks, which has been used on the Mega Amp Spherical Tokamak (MAST). Two current-carrying plasma rings or flux ropes approach each due to mutual attraction, forming a current sheet and subsequently merge through magnetic reconnection into a single plasma torus, with substantial plasma heating. Two-dimensional resistive and Hall-magnetohydrodynamic simulations of this process are reported, including a strong guide field. A model of the merging based on helicity-conserving relaxation to a minimum energy state is also presented, extending previous work to tight-aspect-ratio toroidal geometry. This model leads to a prediction of the final state of the merging, in good agreement with simulations and experiment, as well as the average temperature rise. A relaxation model of reconnection between two or more flux ropes in the solar corona is also described, allowing for different senses of twist, and the implications for heating of the solar corona are discussed.

Published

2015

13. On Flux Rope Stability and Atmospheric Stratification in Models of Coronal Mass Ejections Triggered by Flux Emergence

Author

Vyacheslav S. Lukin, Mark G. Linton, and E. Lee

Subjects

Physics, Photosphere, Solar flare, Microphysics, Stratification (water), FOS: Physical sciences, Astronomy and Astrophysics, Magnetic reconnection, Astrophysics, Mechanics, Space Physics (physics.space-ph), Physics - Plasma Physics, Gravitation, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, Space and Planetary Science, Physics::Space Physics, Coronal mass ejection, Astrophysics::Solar and Stellar Astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Rope

Abstract

Flux emergence is widely recognized to play an important role in the initiation of coronal mass ejections. The Chen-Shibata (2000) model, which addresses the connection between emerging flux and flux rope eruptions, can be implemented numerically to study how emerging flux through the photosphere can impact the eruption of a pre-existing coronal flux rope. The model's sensitivity to the initial conditions and reconnection micro-physics is investigated with a parameter study. In particular, we aim to understand the stability of the coronal flux rope in the context of X-point collapse and the effects of boundary driving in both unstratified and stratified atmospheres. In the absence of driving, we assess the behavior of waves in the vicinity of the X-point. With boundary driving applied, we study the effects of reconnection micro-physics and atmospheric stratification on the eruption. We find that the Chen-Shibata equilibrium can be unstable to an X-point collapse even in the absence of driving due to wave accumulation at the X-point. However, the equilibrium can be stabilized by reducing the compressibility of the plasma, which allows small-amplitude waves to pass through the X-point without accumulation. Simulations with the photospheric boundary driving evaluate the impact of reconnection micro-physics and atmospheric stratification on the resulting dynamics: we show the evolution of the system to be determined primarily by the structure of the global magnetic fields with little sensitivity to the micro-physics of magnetic reconnection; and in a stratified atmosphere, we identify a novel mechanism for producing quasi-periodic behavior at the reconnection site behind a rising flux rope as a possible explanation of similar phenomena observed in solar and stellar flares., Submitted Feb 28, 2014 to, accepted Aug 14, 2014 by Astronomy & Astrophysics. 13 pages, 10 figures, 2 tables

Published

2014

14. Temporal and Spatial Turbulent Spectra of MHD Plasma and an Observation of Variance Anisotropy

Author

Vyacheslav S. Lukin, Michael R. Brown, and David Schaffner

Subjects

Length scale, Physics, Spheromak, Turbulence, FOS: Physical sciences, Astronomy and Astrophysics, Plasma, Physics - Plasma Physics, Space Physics (physics.space-ph), Computational physics, Magnetic field, Plasma Physics (physics.plasm-ph), Solar wind, Physics - Space Physics, Physics::Plasma Physics, Space and Planetary Science, Physics::Space Physics, Magnetohydrodynamics, Anisotropy

Abstract

The nature of MHD turbulence is analyzed through both temporal and spatial magnetic fluctuation spectra. A magnetically turbulent plasma is produced in the MHD wind-tunnel configuration of the Swarthmore Spheromak Experiment (SSX). The power of magnetic fluctuations is projected into directions perpendicular and parallel to a local mean field; the ratio of these quantities shows the presence of variance anisotropy which varies as a function of frequency. Comparison amongst magnetic, velocity, and density spectra are also made, demonstrating that the energy of the turbulence observed is primarily seeded by magnetic fields created during plasma production. Direct spatial spectra are constructed using multi-channel diagnostics and are used to compare to frequency spectra converted to spatial scales using the Taylor Hypothesis. Evidence for the observation of dissipation due to ion inertial length scale physics is also discussed as well as the role laboratory experiment can play in understanding turbulence typically studied in space settings such as the solar wind. Finally, all turbulence results are shown to compare fairly well to a Hall-MHD simulation of the experiment., Comment: 17 pages, 17 figures, Submitted to Astrophysical Journal

Published

2014

15. Magnetic Reconnection in a Weakly Ionized Plasma

Author

James E. Leake, Mark G. Linton, and Vyacheslav S. Lukin

Subjects

Physics, FOS: Physical sciences, Magnetic reconnection, Plasmoid, Plasma, Condensed Matter Physics, Instability, Physics - Plasma Physics, Computational physics, Plasma Physics (physics.plasm-ph), Current sheet, Astrophysics - Solar and Stellar Astrophysics, Physics::Plasma Physics, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Astrophysical plasma, Magnetohydrodynamics, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

Magnetic reconnection in partially ionized plasmas is a ubiquitous phenomenon spanning the range from laboratory to intergalactic scales, yet it remains poorly understood and relatively little studied. Here, we present results from a self-consistent multi-fluid simulation of magnetic reconnection in a weakly ionized reacting plasma with a particular focus on the parameter regime of the solar chromosphere. The numerical model includes collisional transport, interaction and reactions between the species, and optically thin radiative losses. This model improves upon our previous work in Leake et al. 2012 \cite{Leake2012} by considering realistic chromospheric transport coefficients, and by solving a generalized Ohm's law that accounts for finite ion-inertia and electron-neutral drag. We find that during the two dimensional reconnection of a Harris current sheet with an initial width larger than the neutral-ion collisional coupling scale, the current sheet thins until its width becomes less than this coupling scale, and the neutral and ion fluids decouple upstream from the reconnection site. During this process of decoupling, we observe reconnection faster than the single-fluid Sweet-Parker prediction, with recombination and plasma outflow both playing a role in determining the reconnection rate. As the current sheet thins further and elongates it becomes unstable to the secondary tearing instability, and plasmoids are seen. The reconnection rate, outflows and plasmoids observed in this simulation provide evidence that magnetic reconnection in the chromosphere could be responsible for jet-like transient phenomena such as spicules and chromospheric jets., 11 Figures

Published

2013

16. Ionized Plasma and Neutral Gas Coupling in the Sun's Chromosphere and Earth's Ionosphere/Thermosphere

Author

C. R. DeVore, Vyacheslav S. Lukin, Joseph Huba, Mark G. Linton, Holly Gilbert, Alan G. Burns, James E. Leake, J M Krall, Jeffrey P. Thayer, Wenbin Wang, and G. Crowley

Subjects

Physics, Earth and Planetary Astrophysics (astro-ph.EP), FOS: Physical sciences, Astronomy and Astrophysics, Plasma, Physics - Plasma Physics, Space Physics (physics.space-ph), Computational physics, Magnetic field, Plasma Physics (physics.plasm-ph), Coupling (physics), Planetary science, Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, Space and Planetary Science, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Ionosphere, Electric current, Thermosphere, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR), Astrophysics - Earth and Planetary Astrophysics

Abstract

We review physical processes of ionized plasma and neutral gas coupling in the weakly ionized, stratified, electromagnetically-permeated regions of the Sun’s chromosphere and Earth’s ionosphere/thermosphere. Using representative models for each environment we derive fundamental descriptions of the coupling of the constituent parts to each other and to the electric and magnetic fields, and we examine the variation in magnetization of the components. Using these descriptions we compare related phenomena in the two environments, and discuss electric currents, energy transfer and dissipation. We present examples of physical processes that occur in both atmospheres, the descriptions of which have previously been conducted in contrasting paradigms, that serve as examples of how the chromospheric and ionospheric communities can further collaborate. We also suggest future collaborative studies that will help improve our understanding of these two different atmospheres, which while sharing many similarities, also exhibit large disparities in key quantities.

Published

2013

17. PLASMA COMPRESSION IN MAGNETIC RECONNECTION REGIONS IN THE SOLAR CORONA

Author

Elena Provornikova, J. M. Laming, and Vyacheslav S. Lukin

Subjects

Plasma parameters, FOS: Physical sciences, 01 natural sciences, 010305 fluids & plasmas, Current sheet, Physics - Space Physics, Physics::Plasma Physics, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Physics, Astronomy and Astrophysics, Fermi acceleration, Magnetic reconnection, Plasma, Corona, Physics - Plasma Physics, Space Physics (physics.space-ph), Computational physics, Plasma Physics (physics.plasm-ph), Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Beta (plasma physics), Physics::Space Physics, Magnetohydrodynamics

Abstract

It has been proposed that particles bouncing between magnetized flows converging in a reconnection region can be accelerated by the first order Fermi mechanism. Analytical considerations of this mechanism have shown that the spectral index of accelerated particles is related to the total plasma compression within the reconnection region similarly to the case of diffusive shock acceleration mechanism. As a first step to investigate the efficiency of Fermi acceleration in reconnection regions in producing hard energy spectra of particles in the solar corona, we explore the degree of plasma compression that can be achieved at reconnection sites. In particular, we aim to determine the conditions for the strong compressions to form. Using a two-dimensional resistive MHD numerical model we consider a set of magnetic field configurations where magnetic reconnection can occur including a Harris current sheet, a force-free current sheet, and two merging flux ropes. Plasma parameters are taken to be characteristic of the solar corona. Numerical simulations show that strong plasma compressions ($\geq 4$) in the reconnection regions can form when the plasma heating due to reconnection is efficiently removed by fast thermal conduction or radiative cooling process. The radiative cooling process which is negligible in the typical 1 MK corona can play an important role in the low corona/transition region. It is found that plasma compression is expected to be strongest in low-beta plasma $\beta \sim 0.01-0.07$ at reconnection magnetic nulls., Comment: Accepted for publication in the Astrophysical Journal, 36 pages, 11 figures, 1 table

Published

2016

18. Multi-fluid simulations of chromospheric magnetic reconnection in a weakly ionized reacting plasma

Author

E.T. Meier, Vyacheslav S. Lukin, James E. Leake, and Mark G. Linton

Subjects

Physics, FOS: Physical sciences, Astronomy and Astrophysics, Magnetic reconnection, Plasma, Instability, Solar prominence, Physics - Plasma Physics, Computational physics, Plasma Physics (physics.plasm-ph), Current sheet, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, Physics::Plasma Physics, Ionization, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Lundquist number, Chromosphere, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

We present results from the first self-consistent multi-fluid simulations of chromospheric magnetic reconnection in a weakly ionized reacting plasma. We simulate two dimensional magnetic reconnection in a Harris current sheet with a numerical model which includes ion-neutral scattering collisions, ionization, recombination, optically thin radiative loss, collisional heating, and thermal conduction. In the resulting tearing mode reconnection the neutral and ion fluids become decoupled upstream from the reconnection site, creating an excess of ions in the reconnection region and therefore an ionization imbalance. Ion recombination in the reconnection region, combined with Alfv\'{e}nic outflows, quickly removes ions from the reconnection site, leading to a fast reconnection rate independent of Lundquist number. In addition to allowing fast reconnection, we find that these non-equilibria partial ionization effects lead to the onset of the nonlinear secondary tearing instability at lower values of the Lundquist number than has been found in fully ionized plasmas.These simulations provide evidence that magnetic reconnection in the chromosphere could be responsible for jet-like transient phenomena such as spicules and chromospheric jets., Comment: 8 Figures, 32 pages total

Published

2012

19. Turbulence analysis of an experimental flux-rope plasma

Author

A. Wan, Vyacheslav S. Lukin, David Schaffner, and Michael R. Brown

Subjects

Physics, Turbulence, Internal flow, FOS: Physical sciences, Plasma, Condensed Matter Physics, Physics - Plasma Physics, law.invention, Computational physics, Plasma Physics (physics.plasm-ph), Nuclear Energy and Engineering, Physics::Plasma Physics, law, Beta (plasma physics), Intermittency, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Magnetohydrodynamics, Rope, Wind tunnel

Abstract

We have previously generated elongated Taylor double-helix flux rope plasmas in the SSX MHD wind tunnel. These plasmas are remarkable in their rapid relaxation (about one Alfv\'en time) and their description by simple analytical Taylor force-free theory despite their high plasma beta and high internal flow speeds. We report on the turbulent features observed in these plasmas including frequency spectra, autocorrelation function, and probability distribution functions of increments. We discuss here the possibility that the turbulence facilitating access to the final state supports coherent structures and intermittency revealed by non-Gaussian signatures in the statistics. Comparisons to a Hall-MHD simulation of the SSX MHD wind tunnel show similarity in several statistical measures., Comment: 20 pages, 9 figures, submitted to Plasma Physics Controlled Fusion for Special Issue on Flux Ropes

Published

2014

20. Two-fluid simulations of driven reconnection in the mega-ampere spherical tokamak

Author

K. G. McClements, Mykola Gordovskyy, Mikhail Gryaznevich, Adam Stanier, Vyacheslav S. Lukin, and Philippa Browning

Subjects

Physics, Mega Ampere Spherical Tokamak, Toroid, FOS: Physical sciences, Magnetic reconnection, Plasma, Mechanics, Spherical tokamak, Condensed Matter Physics, Space Physics (physics.space-ph), Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), Current sheet, Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics, Physics::Plasma Physics, Physics::Space Physics, Lundquist number, Magnetohydrodynamics, Solar and Stellar Astrophysics (astro-ph.SR)

Abstract

In the merging-compression method of plasma start-up, two flux-ropes with parallel toroidal current are formed around in-vessel poloidal field coils, before merging to form a spherical tokamak plasma. This start-up method, used in the Mega-Ampere Spherical Tokamak (MAST), is studied as a high Lundquist number and low plasma-beta magnetic reconnection experiment. In this paper, 2D fluid simulations are presented of this merging process in order to understand the underlying physics, and better interpret the experimental data. These simulations examine the individual and combined effects of tight-aspect ratio geometry and two-fluid physics on the merging. The ideal self-driven flux-rope dynamics are coupled to the diffusion layer physics, resulting in a large range of phenomena. For resistive MHD simulations, the flux-ropes enter the sloshing regime for normalised resistivity eta < 1E-5. In Hall-MHD three regimes are found for the qualitative behaviour of the current sheet, depending on the ratio of the current sheet width to the ion-sound radius. These are a stable collisional regime, an open X-point regime, and an intermediate regime that is highly unstable to tearing-type instabilities. In toroidal axisymmetric geometry, the final state after merging is a MAST-like spherical tokamak with nested flux-surfaces. It is also shown that the evolution of simulated 1D radial density profiles closely resembles the Thomson scattering electron density measurements in MAST. An intuitive explanation for the origin of the measured density structures is proposed, based upon the results of the toroidal Hall-MHD simulations., 12 pages, 12 figures. The following article has been submitted to Physics of Plasmas. After it is published, it will be found at pop.aip.org

Published

2013