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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

New Observational Insight on Shock Interactions Toward Supernovae and Supernova Remnants

Kilpatrick, Charles Donald, Kilpatrick, Charles Donald January 2016 (has links)
Supernovae (SNe) are energetic explosions that signal the end of a star's life. These events and the supernova remnants (SNRs) they leave behind play a central role in stellar feedback by adding energy and momentum and metals to the interstellar medium (ISM). Emission associated with these feedback processes, especially atomic and molecular line emission as well as thermal and nonthermal continuum emission is known to be enhanced in regions of high density, such as dense circumstellar matter (CSM) around SNe and molecular clouds (MCs). In this thesis, I begin with a brief overview of the physics of SN shocks in Chapter 1, focusing on a foundation for studying pan-chromatic signatures of interactions between SNe and dense environments. In Chapter 2, I examine an unusual SN with signatures of CSM interaction in the form of narrow lines of hydrogen (Type IIn) and thermal continuum emission. This SN appears to belong to a class of Type Ia SNe that shares spectroscopic features with Type IIn SNe. I discuss the difficulties of decomposing spectra in a regime where interaction occurs between SN ejecta and CSM, potentially confusing the underlying SN type. This is followed by a discussion of rebrightening that occurred at late-time in 𝐵 and 𝑉 band photometry of this SN, possibly associated with clumpy or dense CSM at large distances from the progenitor. In Chapter 3, I examine synchrotron emission from Cassiopeia A, observed in the 𝐾ₛ band over multiple epochs. The synchrotron emission is generally diffuse over the remnant, but there is one location in the southwest portion of the remnant where it appears to be enhanced and entrained as knots of emission in the SNR ejecta. I evaluate whether the 𝐾ₛ band knots are dominated by synchrotron emission by comparing them to other infrared and radio imaging that is known to be dominated by synchrotron emission. Concluding that they are likely synchrotron-emitting knots, I measure the magnetic field strength and electron density required for their evolution over the ~ 10 yr baseline they were observed and find 𝐵 ≈ 1.3-5.8 mG and 𝑛ₑ≈ 1,000-15,000 cm⁻³. The magnetic field strengths appear enhanced beyond values required by the adiabatic strong shock limit, arguing in favor of other forms of magnetic field amplification in the shock. In Chapter 4, I again discuss Cassiopeia A and interaction between the remnant and nearby MCs as seen at mid-infrared and millimeter wavelengths. I report detection of a SNR-MC interaction and analyze its signatures in broadened molecular lines. I extend this analysis in Chapter 5 to a large survey for SNR-MC interactions in the ¹²CO 𝐽=2-1 line. Although broadened ¹²CO 𝐽=2-1 line emission should be detectable toward virtually all SNR-MC interactions, I find relatively few examples; therefore, the number of interactions is low. This result favors mechanisms other than supernova feedback as the basic trigger for star formation. In addition, I find no significant association between TeV gamma-ray sources and MC interactions, contrary to predictions that SNR-MC interfaces are the primary venues for cosmic ray acceleration. I end this dissertation in Chapter 6 with a brief summary of my results and two extensions of this work: examining the late-time radio light curves of CSM-interacting SNe for signatures of radio synchrotron emission and dense or clumpy CSM at large distances from the progenitor and re-observing SNR-MC interactions in ¹²CO 𝐽=3-2 in order to verify the presence of shock-heated molecular gas and perform a census on the densities and temperatures of post-shock molecular gas.
2

High-sensitivity analysis of the Cygnus region observed with VERITAS

Krause, Maria 12 April 2017 (has links)
Teilchenschauer können sowohl durch Photonen als auch durch geladene Teilchen erzeugt werden. Letztere kommen etwa 1000-mal häufiger vor als die durch Photonen erzeugten Teilchenschauer. Dies beeinflusst die Sensitivität des VERITAS-Experiments erheblich. Um diese gegenüber Gammastrahlung zu steigern, ist es notwendig, die Gamma-Hadron Separation zu verbessern. In dieser Dissertation wurde eine Analysemethode, basierend auf Boosted Decision Trees (BDTs), entwickelt und für die Analyse der Daten des VERITAS-Observatoriums optimiert. Das große Potential zur Unterscheidung von Teilchenschauern der Photonen und der Hadronen wird anhand ausführlicher Tests und systematischer Studien mit Simulationen von Gammastrahlung und Beobachtungsdaten der kosmischen Strahlung verdeutlicht. Im Vergleich zur Standardanalyse kann die Sensitivität mit Hilfe der BDT Methode deutlich erhöht werden. Die entwickelte und optimierte BDT Methode wird auf Beobachtungsdaten der Cygnus-Region angewandt. Diese ist eine der aktivsten sternbildenden Regionen unserer Galaxie und beherbergt eine Vielzahl von potentiellen kosmischen Teilchenbeschleunigern. Aufgrund der enormen Dichte an potentiellen Quellen sowie der hohen Wahrscheinlichkeit, neue Quellen zu detektieren und zu identifizieren, wurde die Cygnus-Region von April 2007 bis Juni 2012 mit VERITAS beobachtet. Die Beobachtungsdaten wurden mit einer für diese Himmelsregion optimierten Analysetechnik aufbereitet und ausgewertet. Vier Quellen hochenergetischer Gammastrahlung wurden detektiert: VER J2031+415, VER J2019+407, VER J2019+368 und VER J2016+371. Detaillierte spektrale Untersuchungen werden vorgestellt, gefolgt von einer Diskussion möglicher assoziierter Objekte in anderen Wellenlängenbereichen. Schließlich konnten mit Hilfe der verbesserten Sensitivität von VERITAS durch die BDT Methode niedrigere Obergrenzen für den Fluss der hochenergetischen Gammastrahlung von 50 potentiellen Gammastrahlungsquellen abgeleitet werden. / Particle showers can be generated by photons or charged cosmic rays. Before applying any selection requirements, showers initiated by cosmic rays are about 1000 times more common than those initiated by photons. This constitutes a vast amount of background events measured by VERITAS, limiting the sensitivity to gamma rays. To improve the separation power between gamma-ray and cosmic-ray showers, an analysis technique based on Boosted Decision Trees (BDTs) is developed. Extensive tests are performed to study the discrimination capabilities of the BDT method using cosmic-ray data and Monte-Carlo simulations of gamma rays. Compared to the VERITAS standard analysis, the BDT method improves the sensitivity of detecting gamma rays. The BDT method is applied to data obtained from observations of the Cygnus region, one of the most active star-forming regions of our Galaxy. It hosts numerous astrophysical objects capable of accelerating particles to extremely high energies, such as supernova remnants, pulsar wind nebula, binary systems, and associations of massive OB stars. The high density of potential sources and the information from multiwavelength observations led VERITAS to perform observations of the Cygnus region between April 2007 and June 2012. Four sources were detected in very-high-energy gamma rays: VER J2031+415, VER J2019+407, VER J2019+368, and VER J2016+371. They were analysed in detail and compared to possible counterparts measured at other wavelengths. The spectra of the three of the sources were fit to a power law. Two out of three spectra are consistent with those obtained in previous measurements, where the third one shows a softer spectral index than the published result. Finally, the greater sensitivity reached with the BDT method allowed the derivation of the most stringent upper limits to date on 50 potential gamma-ray sources.
3

Structure and nature of gamma-ray binaries by means of VLBI observations

Moldón Vara, Francisco Javier 05 July 2012 (has links)
Gamma-ray binaries are extreme systems that produce non-thermal emission from radio to very-high-energy (above TeV) gamma rays, with the energy output in the spectral energy distribution (SED) dominated by the MeV–GeV photons. Their broadband emission is usually modulated by the orbital cycle of the system, which suggests that the physical conditions are also periodic and reproducible. The diversity of systems, together with the reproducibility of the conditions within each system, makes gamma-ray binaries excellent physical laboratories in which high energy particle acceleration, diffusion, absorption, and radiation mechanisms can be explored. Nevertheless, the number of known gamma-ray binaries is still very limited, and only a six binary systems have been classified as gamma-ray binaries. These systems produce outflows of relativistic particles emitting synchrotron radio emission that extend up to several astronomical units, which correspond to projected angular scales of a few milliarcseconds (mas) at typical distances of 2-3 kpc. Very Long Baseline Interferometry (VLBI) provide mas resolution and therefore can be used to directly see this radio outflow. In this thesis we present VLBI observations of five of the six gamma-ray binaries known. We have revealed for the first time the radio structure of two gamma-ray binaries, and found periodic changes in the structure of other two. Based on these results, we have established the basic properties and behaviour of the radio emission of gamma-ray binaries on AU scales, and we have contributed to find characteristics that are common to all of them. / En los últimos años se ha producido una mejora significativa de los instrumentos que permiten observar fenómenos astrofísicos en rayos gamma de alta y muy alta energía. Gracias a estos avances, se ha podido detectar emisión de rayos gamma en sistemas binarios. Tan sólo seis sistemas binarios han sido clasificados como estrellas binarias de rayos gamma (tres de ellos aún son candidatos). Estos sistemas producen chorros de material relativista que a su vez producen grandes cantidades de energía en todo el espectro electromagnético, desde ondas radio hasta emisión de rayos gamma hasta energías del teraelectronvolt (TeV). Estos chorros se desplazan a alta velocidad produciendo estructuras en escalas de varias unidades astronómicas (UA). Estas estructuras pueden ser observadas directamente mediante técnicas de interferometría radio de muy larga línea de base (VLBI). En esta tesis nos centramos en el estudio de las propiedades morfológicas y astrométricas de binarias de rayos gamma observadas mediante VLBI. De las seis binarias conocidas, se han observado cinco de ellas. Los resultados principales son los siguientes. Se ha detectado estructura extendida en escalas de 120 UA en el sistema binario PSR B1259-63. Esta ha sido la primera evidencia observacional de que púlsares jóvenes no acretantes interaccionando con estrellas jóvenes pueden producir emisión radio extendida. Se ha descubierto que la emisión del sistema LS 5039 muestra cambios periódicos en su morfología, que son estables en escalas de varios años. También se ha determinado el movimiento propio de este sistema y se ha obtenido su trayectoria galáctica en el pasado. Se ha confirmado que el sistema LS I +61 303 muestra variabilidad orbital periódica, aunque presenta cambios significativos en ciertas fases orbitales. Se ha encontrado un desplazamiento del pico de la emisión a varias frecuencias, así como un cambio en sus posiciones relativas. Se ha descubierto emisión extendida procedente de la fuente de rayos gamma HESS J0632+057, y se ha confirmado inequívocamente su asociación con el sistema binario MWC 148. Por último, no se ha encontrado contrapartida radio a la fuente de rayos gamma AGL 2241+4454, cuya contrapartida óptica ha sido propuesta en el sistema MWC 656. Estos resultados permiten sentar las bases de la estructura en escalas de varias UA de los sistemas binarios de rayos gamma, así como su comportamiento en función de la fase orbital. Las características comunes halladas en estos sistemas ha permitido encontrar enlaces observacionales entre estos sistemas, dando consistencia a este particular grupo de estrellas que presentan emisión en rayos gamma.

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