Turbulence in space plasmas: analysis of observations and theoretical mode
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Di Mare, Francesca
Carbone, Vincenzo
Malara, Francesco
Sorriso-Valvo, Luca
Rettino, Alessandro
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Dottorato di Ricerca in Scienze e Tecnologie Fisiche, Chimiche e dei Materiali. Ciclo XXIX; Turbulence represents an universal phenomenon characterizing the dynamics
of different kinds of fluids, like gases, liquids, plasmas, etc., both in nature
and in laboratory devices. It is responsible for the efficient transfer of energy
across scales, making the connection between the macroscopic flow and the
microscopic dissipation of its energy. Moreover, turbulence plays a key role
in determining various phenomena. For instance, the anomalous diffusion of
tracers in a flow may be controlled by the properties of turbulence, and the
transport of charged particles in astrophysical or laboratory plasmas is determined
by the properties of the turbulent magnetic field. Synthetic turbulence
models are a useful tool that provide realistic representations of turbulence,
necessary to test theoretical results, to serve as background fields in some numerical
simulations, and to test analysis tools. Models of 1D and 3D synthetic
turbulence previously developed still required large computational resources.
A new “wavelet-based” model of synthetic turbulence, able to produce a field
with tunable spectral law, intermittency and anisotropy, is presented here.
The rapid algorithm introduced, based on the classic p-model of intermittent
turbulence, allows to reach a broad spectral range using a modest computational
effort. The model has been tested against the standard diagnostics for intermittent turbulence, all showing an excellent response. The same
analysis tools have been used to study a more specific subject, of interest in
space physics, i.e., the turbulence at the interface between the solar wind and
the Earth’s magnetosphere, mediated by the magnetopause. The dynamics
occurring at this boundary depends on various aspects as, e.g., the solar
wind dynamic pressure or the direction of the Interplanetary Magnetic Field
(IMF). If the IMF is directed northward the formation of a wide boundary
layer at the low latitude is observed. This boundary layer is thought to be
the result of the observed plasma transfer, driven by the development of the
Kelvin-Helmholtz instability, originating from the velocity shear between the
solar wind and the almost static near-Earth plasma. Our interest is to described
these phenomena and build a collection of event related to rolled-up
vortices, spatially located on the tail-flank magnetopause, previously studied
by Hasegawa et al. (2006) and Lin et al. (2014). The scope is to study the
properties of plasma turbulence and intermittency inside the magnetosheath,
with the aim to understand the evolution of turbulence, as a result of the development
of KH instability. The analysis we present, represents a complete
and quantitative characterization of turbulence and associated intermittency in this region. It appears that a fluctuating behaviour during the progressive
departure along the Geocentric Solar Magnetosphere (GSM) coordinate
system may exist, and it is visible as a quasi-periodic modulation of the exponent.
The periodicity associated with such oscillation can be estimated to
be approximately 6 − 7 RE, which is consistent with the typical periodicity
of the magnetosheath KH. This suggest that a kind of signature related to
the development of the KH unstable modes could be present in the statistical
properties of the magnetic turbulence.; Università degli Studi della Calabria.Soggetto
Plasma turbulence
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