Modelling the evolution of pulsar wind nebulae / Michael Johannes Vorster

Vorster, Michael Johannes

January 2014

This study focusses on modelling important aspects of the evolution of pulsar wind nebulae using two different approaches. The first uses a hydrodynamic model to simulate the morphological evolution of a spherically-symmetric composite supernova remnant that is expanding into a homogeneous interstellar medium. In order to extend this model, a magnetic field is included in a kinematic fashion, implying that the reaction of the fluid on the magnetic field is taken into account, while neglecting any counter-reaction of the field on the fluid. This approach is valid provided that the ratio of electromagnetic to particle energy in the nebula is small, or equivalently, for a large plasma β environment. This model therefore allows one to not only calculate the evolution of the convection velocity but also, for example, the evolution of the average magnetic field. The second part of this study focusses on calculating the evolution of the energy spectra of the particles in the nebula using a number of particle evolution models. The first of these is a spatially independent temporal evolution model, similar to the models that can be found in the literature. While spatially independent models are useful, a large part of this study is devoted to developing spatially dependent models based on the Fokker-Planck transport equation. Two such models are developed, the first being a spherically-symmetric model that includes the processes of convection, diffusion, adiabatic losses, as well as the non-thermal energy loss processes of synchrotron radiation and inverse Compton scattering. As the magnetic field geometry can lead to the additional transport process of drift, the previous model is extended to an axisymmetric geometry, thereby allowing one to also include this process. / PhD (Space Physics), North-West University, Potchefstroom Campus, 2014

Composite supernova remnants

Morphological evolution

Hydrodynamic

Kinematic magnetic field

Pulsar wind nebulae

Particle evolution models

Fokker-Planck transport equation

Spherically-symmetric

Axisymmetric

Diffusion

Drift

Energy losses

Saamgestelde supernova-oorblyfsels

Morfologiese evolusie

Hidrodinamiese

Kinematiese magneetveld

Pulsarwindnewels

Deeltjie evolusiemodelle

Fokker-Planck transport vergelyking

Sferies-simmetries

Aksiaal-simmetries

Diffusie

Dryf

Energie verliese

Modelling of cosmic ray modulation in the heliosphere by stochastic processes / Roelf du Toit Strauss

Strauss, Roelf du Toit

January 2013

The transport of cosmic rays in the heliosphere is studied by making use of a newly developed modulation model. This model employes stochastic differential equations to numerically solve the relevant transport equation, making use of this approach’s numerical advantages as well as the opportunity to extract additional information regarding cosmic ray transport and the processes responsible for it. The propagation times and energy losses of galactic electrons and protons are calculated for different drift cycles. It is confirmed that protons and electrons lose the same amount of rigidity when they experience the same transport processes. These particles spend more time in the heliosphere, and also lose more energy, in the drift cycle where they drift towards Earth mainly along the heliospheric current sheet. The propagation times of galactic protons from the heliopause to Earth are calculated for increasing heliospheric tilt angles and it is found that current sheet drift becomes less effective with increasing solar activity. Comparing calculated propagation times of Jovian electrons with observations, the transport parameters are constrained to find that 50% of 6 MeV electrons measured at Earth are of Jovian origin. Charge-sign dependent modulation is modelled by simulating the proton to anti-proton ratio at Earth and comparing the results to recent PAMELA observations. A hybrid cosmic ray modulation model is constructed by coupling the numerical modulation model to the heliospheric environment as simulated by a magneto-hydrodynamic model. Using this model, it is shown that cosmic ray modulation persists beyond the heliopause. The level of modulation in this region is found to exhibit solar cycle related changes and, more importantly, is independent of the magnitude of the individual diffusion coefficients, but is rather determined by the ratio of parallel to perpendicular diffusion. / PhD (Space Physics), North-West University, Potchefstroom Campus, 2013

Cosmic rays

Heliosphere

Magneto-hydrodynamics

Stochastic differential equations

Jovian electrons

Charge-sign dependent modulation

Heliopause

Heliospheric current sheet

Propagation times

Particle drifts

Energy losses

Kosmiese strale

Heliosfeer

Magneto-hidrodinamika

Stogastiese differentiaalvergelykings

Jupiter elektrone

Ladingsafhanklike modulasie

Heliopouse

Heliosferiese neutrale vlak

Voortplantingstye

Deeltjie dryf

Energie verliese

Modelling the evolution of pulsar wind nebulae / Michael Johannes Vorster

Vorster, Michael Johannes

January 2014

This study focusses on modelling important aspects of the evolution of pulsar wind nebulae using two different approaches. The first uses a hydrodynamic model to simulate the morphological evolution of a spherically-symmetric composite supernova remnant that is expanding into a homogeneous interstellar medium. In order to extend this model, a magnetic field is included in a kinematic fashion, implying that the reaction of the fluid on the magnetic field is taken into account, while neglecting any counter-reaction of the field on the fluid. This approach is valid provided that the ratio of electromagnetic to particle energy in the nebula is small, or equivalently, for a large plasma β environment. This model therefore allows one to not only calculate the evolution of the convection velocity but also, for example, the evolution of the average magnetic field. The second part of this study focusses on calculating the evolution of the energy spectra of the particles in the nebula using a number of particle evolution models. The first of these is a spatially independent temporal evolution model, similar to the models that can be found in the literature. While spatially independent models are useful, a large part of this study is devoted to developing spatially dependent models based on the Fokker-Planck transport equation. Two such models are developed, the first being a spherically-symmetric model that includes the processes of convection, diffusion, adiabatic losses, as well as the non-thermal energy loss processes of synchrotron radiation and inverse Compton scattering. As the magnetic field geometry can lead to the additional transport process of drift, the previous model is extended to an axisymmetric geometry, thereby allowing one to also include this process. / PhD (Space Physics), North-West University, Potchefstroom Campus, 2014

Composite supernova remnants

Morphological evolution

Hydrodynamic

Kinematic magnetic field

Pulsar wind nebulae

Particle evolution models

Fokker-Planck transport equation

Spherically-symmetric

Axisymmetric

Diffusion

Drift

Energy losses

Saamgestelde supernova-oorblyfsels

Morfologiese evolusie

Hidrodinamiese

Kinematiese magneetveld

Pulsarwindnewels

Deeltjie evolusiemodelle

Fokker-Planck transport vergelyking

Sferies-simmetries

Aksiaal-simmetries

Diffusie

Dryf

Energie verliese

Modelling of cosmic ray modulation in the heliosphere by stochastic processes / Roelf du Toit Strauss

Strauss, Roelf du Toit

January 2013

The transport of cosmic rays in the heliosphere is studied by making use of a newly developed modulation model. This model employes stochastic differential equations to numerically solve the relevant transport equation, making use of this approach’s numerical advantages as well as the opportunity to extract additional information regarding cosmic ray transport and the processes responsible for it. The propagation times and energy losses of galactic electrons and protons are calculated for different drift cycles. It is confirmed that protons and electrons lose the same amount of rigidity when they experience the same transport processes. These particles spend more time in the heliosphere, and also lose more energy, in the drift cycle where they drift towards Earth mainly along the heliospheric current sheet. The propagation times of galactic protons from the heliopause to Earth are calculated for increasing heliospheric tilt angles and it is found that current sheet drift becomes less effective with increasing solar activity. Comparing calculated propagation times of Jovian electrons with observations, the transport parameters are constrained to find that 50% of 6 MeV electrons measured at Earth are of Jovian origin. Charge-sign dependent modulation is modelled by simulating the proton to anti-proton ratio at Earth and comparing the results to recent PAMELA observations. A hybrid cosmic ray modulation model is constructed by coupling the numerical modulation model to the heliospheric environment as simulated by a magneto-hydrodynamic model. Using this model, it is shown that cosmic ray modulation persists beyond the heliopause. The level of modulation in this region is found to exhibit solar cycle related changes and, more importantly, is independent of the magnitude of the individual diffusion coefficients, but is rather determined by the ratio of parallel to perpendicular diffusion. / PhD (Space Physics), North-West University, Potchefstroom Campus, 2013

Cosmic rays

Heliosphere

Magneto-hydrodynamics

Stochastic differential equations

Jovian electrons

Charge-sign dependent modulation

Heliopause

Heliospheric current sheet

Propagation times

Particle drifts

Energy losses

Kosmiese strale

Heliosfeer

Magneto-hidrodinamika

Stogastiese differentiaalvergelykings

Jupiter elektrone

Ladingsafhanklike modulasie

Heliopouse

Heliosferiese neutrale vlak

Voortplantingstye

Deeltjie dryf

Energie verliese