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

Searching for missing baryons through scintillation / Recherche de baryons cachés avec la scintillation

Habibi, Farhang

15 June 2011

L'hydrogène moléculaire diffus et froid peut être l'un des candidats ultimes à la composante baryonique cachée de la Voie Lactée. Nous décrivons une nouvelle voie de recherche de matière transparente dans le disque et le halo galactiques, qui exploite les effets de diffraction et de réfraction de la lumière des étoiles d'arrière-plan. En simulant le retard de phase induit par un milieu turbulent, nous avons calculé la figure d'éclairement sur la terre d'une source étendue pour une bande passante donnée. Nous montrons que dans les cas favorables, la luminosité apparente d'une étoile d'arrière-plan peut être soumise à des fluctuations stochastiques de l'ordre de quelques pour cent sur une échelle de temps caractéristique de quelques minutes. Nous avons recherché de tels effets de scintillation, induits par du gaz moléculaire de nébuleuses visibles (sombres), ainsi que par d'hypothétiques (invisibles) clumpuscules d'hydrogène moléculaire froid du halo, pendant deux nuits avec le détecteur infra-rouge SOFI au foyer du télescope NTT de l'ESO. Parmi les quelques milliers d'étoiles surveillées, nous avons détecté un objet dont les variations sont compatibles avec un fort effet de scintillation à travers une structure turbulente de la nébuleuse B68. Comme par ailleurs aucun effet de scintillation n'a été trouvé vers le Petit Nuage de Magellan, nous sommes en mesure d'établir des limites supérieures sur la contribution des clumpuscules de gaz à la masse du halo galactique. Nous montrons qu'une surveillance à cadence élevée dans la bande visible avec un télescope de diamètre supérieur à quatre mètres équipé d'une caméra à lecture rapide devrait permettre, avec une exposition de quelque millions (d'heures x étoiles), de quantifier ou de borner d'une façon très significative la contribution du gaz moléculaire turbulent au halo Galactique. / Cool molecular hydrogen H2 may be the ultimate possible constituent to the Milky-Way missing baryon. We describe a new way to search for such transparent matter in the Galactic disc and halo, through the diffractive and refractive effects on the light of background stars. By simulating the phase delay induced by a turbulent medium, we computed the corresponding illumination pattern on the earth for an extended source and a given passband. We show that in favorable cases, the light of a background star can be subjected to stochastic fluctuations of the order of a few percent at a characteristic time scale of a few minutes. We have searched for scintillation induced by molecular gas in visible dark nebulae as well as by hypothetical halo clumpuscules of cool molecular hydrogen (H2_He) during two nights, using the NTT telescope and the IR SOFI detector. Amongst a few thousands of monitored stars, we found one light-curve that is compatible with a strong scintillation effect through a turbulent structure in the B68 nebula. Because no candidate were found toward the SMC, we are able to establish upper limits on the contribution of gas clumpuscules to the Galactic halo mass. We show that the short time-scale monitoring of a few 10^6 star _ hour in the visible band with a >4 m telescope and a fast readout camera should allow one to interestingly quantify or constrain the contribution of turbulent molecular gas to the Galactic halo.

Cosmology, Dark matter, Missing baryons

ISM, molecular clouds, turbulence

Estimation of trigger rates, data rates and data volumes for CTA and observations of SNR RX J0852.0−4622 with H.E.S.S.

Paz Arribas, Manuel

26 July 2017

Die vorliegende Arbeit beschäftigt sich mit zwei Aspekten der Gammastrahlungsastronomie. Einerseits studiert sie die Anforderungen an das zukünftige CTA-Observatorium für Gammastrahlung und präsentiert insbesondere Abschätzungen der Datenmengen, die während des Betriebs des Observatoriums anfallen werden. Für das größere CTA-Teleskopfeld auf der Südhalbkugel werden demnach eine Triggerate von 13 kHz und Datenraten von bis zu 2500 MB/s erwartet. Unter der Annahme, dass 15% der Zeit für Beobachtungen genutzt werden können, ergibt sich in 15 Jahren ein Datenvolumen von bis zu 165 PB. Die Implementation eines entsprechenden Systems zur Datenerfassung und -speicherung stellt eine Herausforderung dar, die jedoch mit existierenden Technik bewältigt werden kann. Andererseits befasst sie sich mit dem Supernovaüberrest RX J0852.0-4622 (auch bekannt als Vela Junior), präsentiert die Ergebnisse einer Analyse von Daten, die mit dem H.E.S.S.-Experiment genommen wurden, und geht der Frage nach, ob RX J0852.0-4622 ein kosmischer Teilchenbeschleuniger ist. Dabei erlauben die präzisen Messungen eine im Vergleich zu früheren Veröffentlichungen verbesserte Bestimmung der Eigenschaften der emittierenden Teilchenpopulation. Es ergibt sich, dass das Energiespektrum von RX J0852.0-4622 ein Potenzgesetz ist, das zu hohen Energien hin mit einer Abschneideenergie von 7.2 TeV exponentiell unterdrückt wird. Abschließend wird anhand von Simulation gezeigt, dass CTA die Abschneideenergie von RX J0852.0-4622 signifikant besser bestimmen können wird. Diese genauere Vermessung des Energiespektrums sollte dazu beitragen, den hadronischen oder leptonischen Charakter der Emission aufzuklären. / This work focuses on two different aspects of gamma-ray astronomy. On the one hand, it studies the instrumental challenge posed by the future CTA Observatory by estimating the amount of data to be collected. Based on an analysis of simulated data, the more demanding southern array is expected to have an array trigger rate of 13 kHz, a data rate of up to 2500 MB/s and a data volume after 15 yr of operation and assuming a duty cycle of 15% of up to 165 PB. The design of the data acquisition and storage systems will be a challenge but should be manageable with existing technologies. On the other hand, it studies supernova remnants, by presenting analysis results of the gamma-ray data of the RX J0852.0-4622 supernova remnant (commonly known as Vela Junior) measured with the operating H.E.S.S. experiment and interpreting them in order to check the plausibility of RX J0852.0-4622 being a cosmic ray accelerator. The more precise measurements permit a better determination of the parent particle population properties with respect to previous publications. More precisely, a clear curvature of the spectrum of RX J0852.0-4622 is measured with an exponential energy cut-off at 7.2 TeV. Finally, the analysis of simulated data shows that CTA should be able to significantly improve the determination of the spectral energy cut-off of RX J0852.0-4622, which should help in identifying the nature of the gamma-ray emission.

Astroteilchenphysik

Instrumentation: Detektoren

CTA

H.E.S.S.

Gammastrahlung: Beobachtungen

RX J0852.0-4622

Vela Junior

Supernovaüberreste

PSR J0855-4644

Pulsar Wind Nebel

astroparticle physics

instrumentation: detectors

CTA

H.E.S.S.

gamma-rays: observations

RX J0852.0-4622

Vela Junior

supernova remnants

PSR J0855-4644

pulsar wind nebulae

530 Physik

US 1670

ddc:530

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