Your search keyword '"Pontin, D"' showing total 10 results

1. Topological constraints in the reconnection of vortex braids.

Author

Candelaresi, S., Hornig, G., Podger, B., and Pontin, D. I.

Subjects

REYNOLDS number, SWIRLING flow, KINETIC energy, MAGNETIC fields

Abstract

We study the relaxation of a topologically nontrivial vortex braid with zero net helicity in a barotropic fluid. The aim is to investigate the extent to which the topology of the vorticity field—characterized by braided vorticity field lines—determines the dynamics, particularly the asymptotic behavior under vortex reconnection in evolution at high Reynolds numbers (25 000). Analogous to the evolution of braided magnetic fields in plasma, we find that the relaxation of our vortex braid leads to a simplification of the topology into large-scale regions of opposite swirl, consistent with an inverse cascade of the helicity. The change of topology is facilitated by a cascade of vortex reconnection events. During this process, the existence of regions of positive and negative kinetic helicities imposes a lower bound for the kinetic energy. For the enstrophy, we derive analytically a lower bound given by the presence of unsigned kinetic helicity, which we confirm in our numerical experiments. [ABSTRACT FROM AUTHOR]

Published

2021

2. Quantifying the tangling of trajectories using the topological entropy.

Author

Candelaresi, S., Pontin, D. I., and Hornig, G.

Subjects

*ENTROPY, *FLUID dynamics, *FINITE differences, *TOPOLOGY, *REGRESSION analysis

Abstract

We present a simple method to efficiently compute a lower limit of the topological entropy and its spatial distribution for two-dimensional mappings. These mappings could represent either two-dimensional time-periodic fluid flows or three-dimensional magnetic fields, which are periodic in one direction. This method is based on measuring the length of a material line in the flow. Depending on the nature of the flow, the fluid can be mixed very efficiently which causes the line to stretch. Here, we study a method that adaptively increases the resolution at locations along the line where folds lead to a high curvature. This reduces the computational cost greatly which allows us to study unprecedented parameter regimes. We demonstrate how this efficient implementation allows the computation of the variation of the finite-time topological entropy in the mapping. This measure quantifies spatial variations of the braiding efficiency, important in many practical applications. [ABSTRACT FROM AUTHOR]

Published

2017

3. Dynamic topology and flux rope evolution during non-linear tearing of 3D null point current sheets.

Author

Wyper, P. F. and Pontin, D. I.

Subjects

*MAGNETIC fields, *TEARING instability, *MAGNETIC structure, *BIFURCATION theory, *MAGNETIC flux, *MAGNETOHYDRODYNAMIC waves

Abstract

In this work, the dynamic magnetic field within a tearing-unstable three-dimensional current sheet about a magnetic null point is described in detail. We focus on the evolution of the magnetic null points and flux ropes that are formed during the tearing process. Generally, we find that both magnetic structures are created prolifically within the layer and are non-trivially related. We examine how nulls are created and annihilated during bifurcation processes, and describe how they evolve within the current layer. The type of null bifurcation first observed is associated with the formation of pairs of flux ropes within the current layer. We also find that new nulls form within these flux ropes, both following internal reconnection and as adjacent flux ropes interact. The flux ropes exhibit a complex evolution, driven by a combination of ideal kinking and their interaction with the outflow jets from the main layer. The finite size of the unstable layer also allows us to consider the wider effects of flux rope generation. We find that the unstable current layer acts as a source of torsional magnetohydrodynamic waves and dynamic braiding of magnetic fields. The implications of these results to several areas of heliophysics are discussed. [ABSTRACT FROM AUTHOR]

Published

2014

4. Non-linear tearing of 3D null point current sheets.

Author

Wyper, P. F. and Pontin, D. I.

Subjects

*CURRENT sheets, *NONLINEAR theories, *MAGNETIC reconnection, *LUNDQUIST number, *PROBLEM solving

Abstract

The manner in which the rate of magnetic reconnection scales with the Lundquist number in realistic three-dimensional (3D) geometries is still an unsolved problem. It has been demonstrated that in 2D rapid non-linear tearing allows the reconnection rate to become almost independent of the Lundquist number (the "plasmoid instability"). Here, we present the first study of an analogous instability in a fully 3D geometry, defined by a magnetic null point. The 3D null current layer is found to be susceptible to an analogous instability but is marginally more stable than an equivalent 2D Sweet-Parker-like layer. Tearing of the sheet creates a thin boundary layer around the separatrix surface, contained within a flux envelope with a hyperbolic structure that mimics a spine-fan topology. Efficient mixing of flux between the two topological domains occurs as the flux rope structures created during the tearing process evolve within this envelope. This leads to a substantial increase in the rate of reconnection between the two domains. [ABSTRACT FROM AUTHOR]

Published

2014

5. Three-dimensional null point reconnection regimes.

Author

Priest, E. R. and Pontin, D. I.

Subjects

*MAGNETIC fields, *FIELD theory (Physics), *PLASMA gases, *PARTICLES (Nuclear physics), *NUCLEAR physics

Abstract

Recent advances in theory and computational experiments have shown the need to refine the previous categorization of magnetic reconnection at three-dimensional null points—points at which the magnetic field vanishes. We propose here a division into three different types, depending on the nature of the flow near the spine and fan of the null. The spine is an isolated field line which approaches the null (or recedes from it), while the fan is a surface of field lines which recede from it (or approach it). So-called torsional spine reconnection occurs when field lines in the vicinity of the fan rotate, with current becoming concentrated along the spine so that nearby field lines undergo rotational slippage. In torsional fan reconnection field lines near the spine rotate and create a current that is concentrated in the fan with a rotational flux mismatch and rotational slippage. In both of these regimes, the spine and fan are perpendicular and there is no flux transfer across spine or fan. The third regime, called spine-fan reconnection, is the most common in practice and combines elements of the previous spine and fan models. In this case, in response to a generic shearing motion, the null point collapses to form a current sheet that is focused at the null itself, in a sheet that locally spans both the spine and fan. In this regime the spine and fan are no longer perpendicular and there is flux transfer across both of them. [ABSTRACT FROM AUTHOR]

Published

2009

6. Current sheet formation and nonideal behavior at three-dimensional magnetic null points.

Author

Pontin, D. I., Bhattacharjee, A., and Galsgaard, K.

Subjects

*PLASMA dynamics, *PLASMA electrodynamics, *THREE-dimensional imaging, *MAGNETIC resonance microscopy, *MAGNETOHYDRODYNAMICS, *MAGNETIC fields

Abstract

The nature of the evolution of the magnetic field, and of current sheet formation, at three-dimensional (3D) magnetic null points is investigated. A kinematic example is presented that demonstrates that for certain evolutions of a 3D null (specifically those for which the ratios of the null point eigenvalues are time-dependent), there is no possible choice of boundary conditions that renders the evolution of the field at the null ideal. Resistive magnetohydrodynamics simulations are described that demonstrate that such evolutions are generic. A 3D null is subjected to boundary driving by shearing motions, and it is shown that a current sheet localized at the null is formed. The qualitative and quantitative properties of the current sheet are discussed. Accompanying the sheet development is the growth of a localized parallel electric field, one of the signatures of magnetic reconnection. Finally, the relevance of the results to a recent theory of turbulent reconnection is discussed. [ABSTRACT FROM AUTHOR]

Published

2007

7. Current sheets at three-dimensional magnetic nulls: Effect of compressibility.

Author

Pontin, D. I., Bhattacharjee, A., and Galsgaard, K.

Subjects

*QUANTUM perturbations, *MAGNETOHYDRODYNAMICS, *PLASMA gases, *SHEAR (Mechanics), *PHYSICS

Abstract

The nature of current sheet formation in the vicinity of three-dimensional (3D) magnetic null points is investigated. The particular focus is upon the effect of the compressibility of the plasma on the qualitative and quantitative properties of the current sheet. An initially potential 3D null is subjected to shearing perturbations, as in a previous paper [Pontin et al., Phys. Plasmas 14, 052106 (2007)]. It is found that as the incompressible limit is approached, the collapse of the null point is suppressed and an approximately planar current sheet aligned to the fan plane is present instead. This is the case regardless of whether the spine or fan of the null is sheared. Both the peak current and peak reconnection rate are reduced. The results have a bearing on previous analytical solutions for steady-state reconnection in incompressible plasmas, implying that fan current sheet solutions are dynamically accessible, while spine current sheet solutions are not. [ABSTRACT FROM AUTHOR]

Published

2007

8. Current singularities at finitely compressible three-dimensional magnetic null points.

Author

Pontin, D. I. and Craig, I. J. D.

Subjects

*MAGNETIC fields, *MAGNETOHYDRODYNAMICS, *FLUID dynamics, *PLASMA dynamics, *QUANTUM perturbations, *PERTURBATION theory

Abstract

The formation of current singularities at line-tied two- and three-dimensional (2D and 3D, respectively) magnetic null points in a nonresistive magnetohydrodynamic environment is explored. It is shown that, despite the different separatrix structures of 2D and 3D null points, current singularities may be initiated in a formally equivalent manner. This is true no matter whether the collapse is triggered by flux imbalance within closed, line-tied null points or driven by externally imposed velocity fields in open, incompressible geometries. A Lagrangian numerical code is used to investigate the finite amplitude perturbations that lead to singular current sheets in collapsing 2D and 3D null points. The form of the singular current distribution is analyzed as a function of the spatial anisotropy of the null point, and the effects of finite gas pressure are quantified. It is pointed out that the pressure force, while never stopping the formation of the singularity, significantly alters the morphology of the current distribution as well as dramatically weakening its strength. The impact of these findings on 2D and 3D magnetic reconnection models is discussed. [ABSTRACT FROM AUTHOR]

Published

2005

9. A fully magnetohydrodynamic simulation of three-dimensional non-null reconnection.

Author

Pontin, D. I., Galsgaard, K., Hornig, G., and Priest, E. R.

Subjects

*MAGNETIC fields, *MAGNETIC flux, *ELECTROMAGNETIC induction, *MAGNETICS, *ELECTRIC fields, *ELECTROMAGNETIC fields

Abstract

A knowledge of the nature of fully three-dimensional magnetic reconnection is crucial in understanding a great many processes in plasmas. It has been previously shown that in the kinematic regime the evolution of magnetic flux in three-dimensional reconnection is very different from two dimensions. In this paper a numerical fully magnetohydrodynamic simulation is described, in which this evolution is investigated. The reconnection takes place in the absence of a magnetic null point, and the nonideal region is localized in the center of the domain. The effect of differently prescribed resistivities is considered. The magnetic field is stressed by shear boundary motions, and a current concentration grows within the volume. A stagnation-point flow develops, with strong outflow jets emanating from the reconnection region. The behavior of the magnetic flux matches closely that discovered in the kinematic regime. In particular, it is found that no unique field line velocity exists, and that as a result field lines change their connections continually and continuously throughout the nonideal region. In order to describe the motion of magnetic flux within the domain, it is therefore necessary to use two different field line velocities. The importance of a component of the electric field parallel to the magnetic field is also demonstrated. [ABSTRACT FROM AUTHOR]

Published

2005

10. Kelvin-Helmholtz instability in a current-vortex sheet at a 3D magnetic null.

Author

Wyper, P. F. and Pontin, D. I.

Subjects

*MAGNETICS, *MAGNETOSPHERE, *MAGNETIC fields, *PLASMA pressure, *HYDRODYNAMICS

Abstract

We report here, for the first time, an observed instability of a Kelvin-Helmholtz nature occurring in a fully three-dimensional (3D) current-vortex sheet at the fan plane of a 3D magnetic null point. The current-vortex layer forms self-consistently in response to foot point driving around the spine lines of the null. The layer first becomes unstable at an intermediate distance from the null point, with the instability being characterized by a rippling of the fan surface and a filamentation of the current density and vorticity in the shear layer. Owing to the 3D geometry of the shear layer, a branching of the current filaments and vortices is observed. The instability results in a mixing of plasma between the two topologically distinct regions of magnetic flux on either side of the fan separatrix surface, as flux is reconnected across this surface. We make a preliminary investigation of the scaling of the system with the dissipation parameters. Our results indicate that the fan plane separatrix surface is an ideal candidate for the formation of current-vortex sheets in complex magnetic fields and, therefore, the enhanced heating and connectivity change associated with the instabilities of such layers. [ABSTRACT FROM AUTHOR]

Published

2013