39 research outputs found
Current singularities at Quasi-separatrix layers and three-dimensional magnetic nulls
The open problem of how singular current structures form in line-tied, three-dimensional magnetic fields is addressed. A Lagrangian magneto-frictional relaxation method is employed to model the field evolution toward the final near-singular state. Our starting point is an exact force-free solution of the governing magnetohydrodynamic equations that is sufficiently general to allow for topological features like magnetic nulls to be inside or outside the computational domain, depending on a simple set of parameters. Quasi-separatrix layers (QSLs) are present in these structures and, together with the magnetic nulls, they significantly influence the accumulation of current. It is shown that perturbations affecting the lateral boundaries of the configuration lead not only to collapse around the magnetic null but also to significant QSL currents. Our results show that once a magnetic null is present, the developing currents are always attracted to that specific location and show a much stronger scaling with resolution than the currents that form along the QSL. In particular, the null-point scalings can be consistent with models of "fast" reconnection. The QSL currents also appear to be unbounded but give rise to weaker singularities, independent of the perturbation amplitude
Anisotropic diffusion of galactic cosmic ray protons and their steady-state azimuthal distribution
Galactic transport models for cosmic rays involve the diffusive motion of
these particles in the interstellar medium. Due to the large-scale structured
galactic magnetic field this diffusion is anisotropic with respect to the local
field direction. We included this transport effect along with continuous loss
processes in a quantitative model of galactic propagation for cosmic ray
protons which is based on stochastic differential equations. We calculated
energy spectra at different positions along the Sun's galactic orbit and
compared them to the isotropic diffusion case. The results show that a larger
amplitude of variation as well as different spectral shapes are obtained in the
introduced anisotropic diffusion scenario and emphasize the need for accurate
galactic magnetic field models.Comment: 7 pages, 5 figures, accepted for publication in A&
Parameter estimation of superdiffusive motion of energetic particles upstream of heliospheric shocks
In-situ spacecraft observations recently suggested that the transport of
energetic particles accelerated at heliospheric shocks can be anomalous, i.e.
the mean square displacement can grow non-linearly in time. In particular, a
new analysis technique has permitted the study of particle transport properties
from energetic particle time profiles upstream of interplanetary shocks.
Indeed, the time/spatial power laws of the differential intensity upstream of
several shocks are indicative of superdiffusion. A complete determination of
the key parameters of superdiffusive transport comprises the power-law index,
the superdiffusion coefficient, the related transition scale at which the
energetic particle profiles turn to decay as power laws, and the energy
spectral index of the shock accelerated particles. Assuming large-scale spatial
homogeneity of the background plasma, the power-law behaviour can been derived
from both a (microscopic) propagator formalism and a (macroscopic) fractional
transport equation. We compare the two approaches and find a relation between
the diffusion coefficients used in the two formalisms. Based on the assumption
of superdiffusive transport, we quantitatively derive these parameters by
studying energetic particle profiles observed by the Ulysses and Voyager 2
spacecraft upstream of shocks in the heliosphere, for which a superdiffusive
particle transport has previously been observed. Further, we have jointly
studied the electron energy spectra, comparing the values of the spectral
indices observed with those predicted by the standard diffusive shock
acceleration theory and by a model based on superdiffusive transport. For a
number of interplanetary shocks and for the solar wind termination shock, for
the first time we obtain the anomalous diffusion constants and the scale at
which the probability of particle free paths changes to a power-law...Comment: 5 Figure
Numerical Simulation of Current Sheet Formation in a Quasi-Separatrix Layer using Adaptive Mesh Refinement
The formation of a thin current sheet in a magnetic quasi-separatrix layer
(QSL) is investigated by means of numerical simulation using a simplified
ideal, low-, MHD model. The initial configuration and driving boundary
conditions are relevant to phenomena observed in the solar corona and were
studied earlier by Aulanier et al., A&A 444, 961 (2005). In extension to that
work, we use the technique of adaptive mesh refinement (AMR) to significantly
enhance the local spatial resolution of the current sheet during its formation,
which enables us to follow the evolution into a later stage. Our simulations
are in good agreement with the results of Aulanier et al. up to the calculated
time in that work. In a later phase, we observe a basically unarrested collapse
of the sheet to length scales that are more than one order of magnitude smaller
than those reported earlier. The current density attains correspondingly larger
maximum values within the sheet. During this thinning process, which is finally
limited by lack of resolution even in the AMR studies, the current sheet moves
upward, following a global expansion of the magnetic structure during the
quasi-static evolution. The sheet is locally one-dimensional and the plasma
flow in its vicinity, when transformed into a co-moving frame, qualitatively
resembles a stagnation point flow. In conclusion, our simulations support the
idea that extremely high current densities are generated in the vicinities of
QSLs as a response to external perturbations, with no sign of saturation.Comment: 6 Figure
First results of the SA Agulhas II mobile mini-neutron monitor: Instrumental characterization and environmental sensitivity
We present the first results of a new redesigned version of the mini-neutron monitor installed on the South African Research vessel, the SA Agulhas II. Measurements taken from the 2019/2020 relief voyages are presented. We show that the instrument is very sensitive to temperature variations when the ambient temperature is below 3oC. This is believed to be an instrumental effect. Additionally, we show the presence of high-frequency interference in the calculated waiting time distributions when the vessel reaches polar latitudes. We show that these periodic variations are only present in the intensity of secondary atmospheric particles and most likely related to the operation of the vessel’s ice radar. We are currently looking at moving the instrument to a more suitable location on board the SA Agulhas II where we will hopefully be able to operate the instrument in a continuous fashion for several years to come