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A study of cosmic ray anisotropies in the heliosphere / Godfrey Sibusiso NkosiNkosi, Godfrey Sibusiso January 2006 (has links)
Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2007.
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Aspects of the modulation of cosmic rays in the outer heliosphere / by Mabedle Donald NgobeniNgobeni, Mabedle Donald January 2006 (has links)
A time-dependent two-dimensional (2D) modulation model including drifts, the solar wind
tennination shock (TS) with diffusive shock acceleration and a heliosheath based on the
Parker (1965) transport equation is used to study the modulation of galactic cosmic rays
(GCRs) and the anomalous component of cosmic rays (ACRs) in the heliosphere. In
particular, the latitude dependence of the TS compression ratio and injection efficiency of the
ACRs (source strength) based on the hydrodynamic modeling results of Scherer et al. (2006)
is used for the first time in a modulation model. The subsequent effects on differential
intensities for both GCRs and ACRs are illustrated, comparing them to the values without a
latitude dependence for these parameters. It is found that the latitude dependence of these
parameters is important and that it enables an improved description of the modulation of
ACRs beyond the TS. With this modeling approach (without fitting observations) to the
latitude dependence of the two parameters, it is possible to obtain a TS spectrum for ACRs at
a polar angle of B = 55" that qualitatively approximates the main features of the Voyager 1
observations. This positive result has to be investigated further. Additionally, it is shown that
the enhancement of the cosmic ray intensity just below the cut-off energy found for the ACR
at the TS in an A < 0 magnetic polarity cycle in the equatorial plane with the latitude
independent scenario, disappears in this region when the latitude dependence of the
compression ratio and injection efficiency is assumed. Subsequent effects of these scenarios
are illustrated on the global anisotropy vector of both GCRs and ACRs as the main theme of
this work. For this purpose the radial and latitudinal gradients for GCRs and ACRs were
accurately computed. The radial and latitudinal anisotropy components were then computed
as a function of energy, radial distance and polar angle. It is also the first time that the
anisotropy vector is comprehensively calculated in such a global approach to cosmic ray
modeling in the heliosphere, in particular for ACRs. It is shown that the anisotropy vector
inside (up-stream) and outside (down-stream) the TS behaves in a complicated way, so care
must be taken in interpreting it. It is found that the latitude dependence of the two mentioned
parameters can alter the direction (sign) of the anisotropy vector. Its behaviour beyond the TS
is markedly different from inside the TS, mainly because of the slower solar wind velocity,
with less dependence on the magnetic polarity cycles. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2007.
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Aspects of the modulation of cosmic rays in the outer heliosphere / by Mabedle Donald NgobeniNgobeni, Mabedle Donald January 2006 (has links)
A time-dependent two-dimensional (2D) modulation model including drifts, the solar wind
tennination shock (TS) with diffusive shock acceleration and a heliosheath based on the
Parker (1965) transport equation is used to study the modulation of galactic cosmic rays
(GCRs) and the anomalous component of cosmic rays (ACRs) in the heliosphere. In
particular, the latitude dependence of the TS compression ratio and injection efficiency of the
ACRs (source strength) based on the hydrodynamic modeling results of Scherer et al. (2006)
is used for the first time in a modulation model. The subsequent effects on differential
intensities for both GCRs and ACRs are illustrated, comparing them to the values without a
latitude dependence for these parameters. It is found that the latitude dependence of these
parameters is important and that it enables an improved description of the modulation of
ACRs beyond the TS. With this modeling approach (without fitting observations) to the
latitude dependence of the two parameters, it is possible to obtain a TS spectrum for ACRs at
a polar angle of B = 55" that qualitatively approximates the main features of the Voyager 1
observations. This positive result has to be investigated further. Additionally, it is shown that
the enhancement of the cosmic ray intensity just below the cut-off energy found for the ACR
at the TS in an A < 0 magnetic polarity cycle in the equatorial plane with the latitude
independent scenario, disappears in this region when the latitude dependence of the
compression ratio and injection efficiency is assumed. Subsequent effects of these scenarios
are illustrated on the global anisotropy vector of both GCRs and ACRs as the main theme of
this work. For this purpose the radial and latitudinal gradients for GCRs and ACRs were
accurately computed. The radial and latitudinal anisotropy components were then computed
as a function of energy, radial distance and polar angle. It is also the first time that the
anisotropy vector is comprehensively calculated in such a global approach to cosmic ray
modeling in the heliosphere, in particular for ACRs. It is shown that the anisotropy vector
inside (up-stream) and outside (down-stream) the TS behaves in a complicated way, so care
must be taken in interpreting it. It is found that the latitude dependence of the two mentioned
parameters can alter the direction (sign) of the anisotropy vector. Its behaviour beyond the TS
is markedly different from inside the TS, mainly because of the slower solar wind velocity,
with less dependence on the magnetic polarity cycles. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2007.
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A study of cosmic ray anisotropies in the heliosphere / Godfrey Sibusiso NkosiNkosi, Godfrey Sibusiso January 2006 (has links)
The three-dimensional (3D) steady-state electron modulation model of Ferreira (2002),
based on Parker (1965) transport equation, is used to study the modulation of the 7 MeV
galactic and Jovian electron anisotropies in the inner heliosphere. The Jovian electrons
are produced in Jupiter's magnetosphere which is situated at ~ 5 AU in the ecliptic plane.
The propagation of these particles is mainly described by the diffusion tensor applicable
for the inner heliosphere. Some of the elements of the diffusion tensor are revisited in
order to establish what contribution they make to the three-dimensional anisotropy vector
and its components in the inner heliosphere. The 'drift' term is neglected since the focus
of this study is on low-energy electrons. The effects on the electron anisotropy of
different scenarios when changing the solar wind speed from minimum to maximum
activity is illustrated. The effects on both the galactic and Jovian electron anisotropy of
changing the polar perpendicular coefficient, in particular, are illustrated. It is shown that
the computed Jovian electron anisotropy dominates the galactic anisotropy close to the
Jovian electron source at ~5 AU, as expected, testifying to the validity of the3D-model.
For the latitudinal anisotropy, the polar perpendicular diffusion plays a dominant role for
Jovian electrons close to the source, with the polar gradient becoming the dominant factor
away from the electron source. Of all three anisotropy components, the azimuthal
anisotropy is dominant in the equatorial plane close to the source. It is found that there is
a large azimuthal gradient close to the source because the low-energy electrons tend to
follow the heliospheric magnetic field more closely than higher energy particles. The
transition of the solar wind speed from minimum to intermediate to maximum solar
activity condition was used to illustrate the modulation of the magnitude of the 7 MeV
total anisotropy vector along the Ulysses trajectory. It was found that during the two
encounters with the planet a maximum anisotropy of 38% was computed but with
different anisotropy-timepeaks as the approach to Jupiter was different. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2007.
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A study of cosmic ray anisotropies in the heliosphere / Godfrey Sibusiso NkosiNkosi, Godfrey Sibusiso January 2006 (has links)
The three-dimensional (3D) steady-state electron modulation model of Ferreira (2002),
based on Parker (1965) transport equation, is used to study the modulation of the 7 MeV
galactic and Jovian electron anisotropies in the inner heliosphere. The Jovian electrons
are produced in Jupiter's magnetosphere which is situated at ~ 5 AU in the ecliptic plane.
The propagation of these particles is mainly described by the diffusion tensor applicable
for the inner heliosphere. Some of the elements of the diffusion tensor are revisited in
order to establish what contribution they make to the three-dimensional anisotropy vector
and its components in the inner heliosphere. The 'drift' term is neglected since the focus
of this study is on low-energy electrons. The effects on the electron anisotropy of
different scenarios when changing the solar wind speed from minimum to maximum
activity is illustrated. The effects on both the galactic and Jovian electron anisotropy of
changing the polar perpendicular coefficient, in particular, are illustrated. It is shown that
the computed Jovian electron anisotropy dominates the galactic anisotropy close to the
Jovian electron source at ~5 AU, as expected, testifying to the validity of the3D-model.
For the latitudinal anisotropy, the polar perpendicular diffusion plays a dominant role for
Jovian electrons close to the source, with the polar gradient becoming the dominant factor
away from the electron source. Of all three anisotropy components, the azimuthal
anisotropy is dominant in the equatorial plane close to the source. It is found that there is
a large azimuthal gradient close to the source because the low-energy electrons tend to
follow the heliospheric magnetic field more closely than higher energy particles. The
transition of the solar wind speed from minimum to intermediate to maximum solar
activity condition was used to illustrate the modulation of the magnitude of the 7 MeV
total anisotropy vector along the Ulysses trajectory. It was found that during the two
encounters with the planet a maximum anisotropy of 38% was computed but with
different anisotropy-timepeaks as the approach to Jupiter was different. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2007.
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Modelling of galactic cosmic ray electrons in the heliosphere / Nndanganeni, R.R.Nndanganeni, Rendani Rejoyce January 2012 (has links)
The Voyager 1 spacecraft is now about 25 AU beyond the heliospheric termination shock and
soon it should encounter the outer boundary of the heliosphere, the heliopause. This is set to
be at 120 AU in the modulation model used for this study. This implies that Voyager 1, and
soon afterwards also Voyager 2, should be able to measure the heliopause spectrum, to be
interpreted as the lowest possible local interstellar spectrum, for low energy galactic electrons
(1 MeV to 120 MeV). This could give an answer to a long outstanding question about the
spectral shape (energy dependence) of the galactic electron spectrum at these low energies.
These in situ electron observations from Voyager 1, until the year 2010 when it was already
beyond 112 AU, are used for a comparative study with a comprehensive three dimensional
numerical model for the solar modulation of galactic electrons from the inner to the outer
heliosphere.
A locally developed steady state modulation model which numerically solves the relevant
heliospheric transport equation is used to compute and study modulated electron spectra from
Earth up to the heliopause. The issue of the spectral shape of the local interstellar spectrum at
these low energies is specifically addressed, taking into account modulation in the inner
heliosheath, up to the heliopause, including the effects of the transition of the solar wind
speed from supersonic to subsonic in the heliosheath. Modulated electron spectra from the
inner to the outer heliosphere are computed, together with radial and latitudinal profiles,
focusing on 12 MeV electrons. This is compared to Voyager 1 observations for the energy
range 6–14 MeV. A heliopause electron spectrum is computed and presented as a new
plausible local interstellar spectrum from 30 GeV down to 10 MeV.
The comparisons between model predictions and observations from Voyager 1 and at Earth
(e.g. from the PAMELA mission and from balloon flights) and in the inner heliosphere (e.g.
from the Ulysses mission) are made. This enables one to make conclusions about diffusion
theory applicable to electrons in the heliosphere, in particular the rigidity dependence of
diffusion perpendicular and parallel to the local background solar magnetic field. A general
result is that the rigidity dependence of both parallel and perpendicular diffusion coefficients
needs to be constant below P < 0.4 GV and only be allowed to increase above this rigidity to
assure compatibility between the modeling and observations at Earth and especially in the outer heliosphere. A modification in the radial dependence of the diffusion coefficients in the
inner heliosheath is required to compute realistic modulation in this region. With this study,
estimates of the intensity of low energy galactic electrons at Earth can be made. A new local
interstellar spectrum is computed for these low energies to improve understanding of the
modulation galactic electrons as compared to previous results described in the literature. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2012.
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Modelling of galactic cosmic ray electrons in the heliosphere / Nndanganeni, R.R.Nndanganeni, Rendani Rejoyce January 2012 (has links)
The Voyager 1 spacecraft is now about 25 AU beyond the heliospheric termination shock and
soon it should encounter the outer boundary of the heliosphere, the heliopause. This is set to
be at 120 AU in the modulation model used for this study. This implies that Voyager 1, and
soon afterwards also Voyager 2, should be able to measure the heliopause spectrum, to be
interpreted as the lowest possible local interstellar spectrum, for low energy galactic electrons
(1 MeV to 120 MeV). This could give an answer to a long outstanding question about the
spectral shape (energy dependence) of the galactic electron spectrum at these low energies.
These in situ electron observations from Voyager 1, until the year 2010 when it was already
beyond 112 AU, are used for a comparative study with a comprehensive three dimensional
numerical model for the solar modulation of galactic electrons from the inner to the outer
heliosphere.
A locally developed steady state modulation model which numerically solves the relevant
heliospheric transport equation is used to compute and study modulated electron spectra from
Earth up to the heliopause. The issue of the spectral shape of the local interstellar spectrum at
these low energies is specifically addressed, taking into account modulation in the inner
heliosheath, up to the heliopause, including the effects of the transition of the solar wind
speed from supersonic to subsonic in the heliosheath. Modulated electron spectra from the
inner to the outer heliosphere are computed, together with radial and latitudinal profiles,
focusing on 12 MeV electrons. This is compared to Voyager 1 observations for the energy
range 6–14 MeV. A heliopause electron spectrum is computed and presented as a new
plausible local interstellar spectrum from 30 GeV down to 10 MeV.
The comparisons between model predictions and observations from Voyager 1 and at Earth
(e.g. from the PAMELA mission and from balloon flights) and in the inner heliosphere (e.g.
from the Ulysses mission) are made. This enables one to make conclusions about diffusion
theory applicable to electrons in the heliosphere, in particular the rigidity dependence of
diffusion perpendicular and parallel to the local background solar magnetic field. A general
result is that the rigidity dependence of both parallel and perpendicular diffusion coefficients
needs to be constant below P < 0.4 GV and only be allowed to increase above this rigidity to
assure compatibility between the modeling and observations at Earth and especially in the outer heliosphere. A modification in the radial dependence of the diffusion coefficients in the
inner heliosheath is required to compute realistic modulation in this region. With this study,
estimates of the intensity of low energy galactic electrons at Earth can be made. A new local
interstellar spectrum is computed for these low energies to improve understanding of the
modulation galactic electrons as compared to previous results described in the literature. / Thesis (M.Sc. (Physics))--North-West University, Potchefstroom Campus, 2012.
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