Global ETD Search

131	The role of rotation and magnetic fields in a core collapse supernova Akiyama, Shizuka 05 August 2013 (has links) While the process that converts implosion into explosion in core collapse supernovae is poorly understood, their observed asphericity provides new constraints on the physics of these events. Since pulsars are rotating and magnetized neutron stars, there is no doubt that rotation and magnetic fields are inherent to the exploding engine. We have shown that magnetic field amplification is an inevitable by-product of the differential rotation that accompanies core-collapse. We performed 1D core-collapse simulations of rotating iron cores with various rotational profiles and velocities. We found that differential rotation was a generic feature of rotating iron core collapse. As a result, the magnetorotational instability (MRI) generates magnetic fields of order 10¹⁵⁻¹⁷ G in a few tens of milliseconds where the negative shear is the strongest. Although magnetic fields of order 10¹⁵⁻¹⁷ G are very strong, they are not strong enough to modify the equation of state of degenerate electron gas near the proto-neutron star. The corresponding MHD luminosity available is ~10⁵² erg s⁻¹, which can modify the explosion dynamics if the power is sustained for a fraction of a second. When rotational effects are included, we found that there is a critical iron core rotation rate that gives the most rapidly rotating proto-neutron star, faster than which the rotational velocity of the proto-neutron star decreases due to centrifugal support. This non-monotonic behavior of post-collapse core rotation suggests that the progenitor of the most rapidly rotating proto-neutron star is not the most rapidly rotating iron core, but that those iron cores with nearly the critical initial rotation rate may produce the maximum proto-neutron star rotation, the strongest magnetic fields, and the most robust supernova explosions. Even small rotation may induce non-axisymmetric instabilities, which drive magneto-acoustic flux in to the mantle, transporting enegy out of the proto-neutron star to the region near the stalled shock. Further implications for rotation and magnetic fields, pulsars and magnetars, and jet formation mechanisms are discussed. / text Supernova Core collapse Iron core Proto-neutron star Rotation Magnetic fields
132	Infrared Light Curves of Type Ia Supernovae Friedman, Andrew 12 September 2012 (has links) This thesis presents the CfAIR2 data set, which includes over 4000 near-Infrared (NIR) $JHK_s$-band measurements of 104 Type Ia Supernovae (SN Ia) observed from 2005-2011 using PAIRITEL, the 1.3-m Peters Automated InfraRed Imaging TELescope at the Fred Lawrence Whipple Observatory (FLWO) on Mount Hopkins, Arizona. While the discovery of dark energy and most subsequent supernova cosmology has been performed using optical and Ultraviolet wavelength observations of SN Ia, a growing body of evidence suggests that NIR SN Ia observations will be crucial for future cosmological studies. Whereas SN Ia observed at optical wavelengths have been shown to be excellent standardizeable candles, using empirical correlations between luminosity, light curve shape, and color, the CfAIR2 data set strengthens the evidence that SN Ia at NIR wavelengths are essentially standard candles, even without correction for light-curve shape or for reddening. CfAIR2 was obtained as part of the CfA Supernova Program, an ongoing multi-wavelength follow-up effort at FLWO designed to observe high-quality, densely sampled light curves and spectra of hundreds of low-redshift SN Ia. CfAIR2 is the largest homogeneously observed and processed NIR data set of its kind to date, nearly tripling the number of individual $JHK_s$ band observations and nearly doubling the set of SN Ia with published NIR light curves in the literature. Matched only by the recently published Carnegie Supernova Project sample, CfAIR2 complements the large and growing set of low-redshift optical and NIR SN Ia observations obtained by the CfA and other programs, making this data set a unique and particularly valuable local universe anchor for future supernova cosmology. / Astronomy astronomy astrophysics cosmology infrared observational astronomy robotic telescopes supernova type Ia supernovae
133	X-ray observations of the young pulsar wind nebula G21.5–0.9 and the evolved pulsar wind nebulae CTB 87 (G74.9+1.2) and G63.7+1.1 Matheson, Heather January 2015 (has links) Pulsar wind nebulae (PWNe), nebulae harbouring a rotation-powered neutron star that was born in a supernova, provide opportunities to study highly relativistic pulsar winds and their interaction with the surrounding medium. Particularly interesting are PWNe that do not show any sign of the expected surrounding SNR shell and were thought to be born in subenergetic explosions or with unusual progenitors. The detection of a shell around one such PWN suggested that shells are indeed produced but may be faint due to unseen shocked ejecta, a low density environment, and/or a young age that has not yet allowed the shell to brighten and become visible. Here, by using observational X-ray data from modern telescopes with excellent spatial and energy resolution (Chandra and XMM-Newton), we target PWNe that do not have prominent SNR shells, and are known to be in varied environments, to further explore the characteristics of this growing, but poorly explored, class of PWNe. By combining imaging and spectroscopic results, we study the morphology of the PWNe, search for thermal emission from shock-heated material, investigate the energetics of the nebulae, and search for candidates for the neutron stars powering the nebulae. We find that while the faint shell surrounding G21.5–0.9 can be explained as a young PWN evolving in a low density medium, CTB 87 (G74.9+1.2) appears to be in an advanced stage of evolution, and G63.7+1.1 appears to be both in an advanced stage of evolution and in a dense environment. By performing spatially resolved spectroscopy, we have shown how the spectral characteristics vary across the PWNe, and note that more data will place better constraints on possible thermal emission in these remnants. The imaging portion of these studies has revealed intriguing large-scale morphologies for CTB 87 and G63.7+1.1, as well as a torus-jet structure in CTB 87 and neutron star candidates in both CTB 87 and G63.7+1.1. We conclude that both CTB 87 and G63.7+1.1 are likely interacting with the supernova remnant reverse shock, and CTB 87 may be additionally influenced by the motion of its neutron star. pulsar wind nebula supernova remnant X-ray Chandra X-ray Observatory XMM-Newton
134	Ανίχνευση και μελέτη υπολειμμάτων υπερκαινοφανών και εξωγαλαξιακής σκόνης Αλικάκος, Ιωάννης 26 April 2012 (has links) Η διδακτορική διατριβή βασίζεται σε οπτικές παρατηρήσεις που πραγματοποιήθηκαν από τα τηλεσκόπια του αστεροσκοπείου του Σκίνακα (το οποίο βρίσκεται στην Κρήτη) και από το τηλεσκόπιο Ισαάκ Νιούτον (που βρίσκεται στη Λα Πάλμα στα Κανάρια νησιά). Από τις παρατηρήσεις αυτές, (οπτικές εικόνες και φάσματα) ανακαλύφθηκαν σε μία περιοχή εβδομήντα τετραγωνικών λεπτών του τόξου της μοίρας, έξι υπολείμματα υπερκαινοφανών αστέρων τα οποία δεν αναγράφονται σε καμία βιβλιογραφία. Τα υπολείμματα αυτά, λόγω της ίδιας περίπου απόστασης που απέχουν, ενδεχομένως να προέρχονται από αλληλεπιδράσεις υπερκαινοφανών αστέρων, οπού η έκρηξη του ενός αστέρα, επιταχύνει την έκρηξη του πλησιέστερου σε αυτόν αστέρα που βρίσκεται στο τελευταίο στάδιο, όταν το ωστικό κύμα διέλθει από αυτόν, δημιουργώντας έτσι μια φυσαλίδα υπολειμμάτων υπερκαινοφανών. Το σημαντικό με αυτή την μελέτη είναι ότι για πρώτη φορά παρατηρήθηκαν στον Γαλαξία μας, στο οπτικό μέρος του φάσματος, μια περιοχή με τόσα υπολείμματα υπερκαινοφανών, παρέχοντάς μας την δυνατότητα να μελετήσουμε τον ρυθμό των εκρήξεων των υπερκαινοφανών με αυτόν της δημιουργίας των υπολειμμάτων τους, και να εξάγουμε συμπεράσματα για τον ρυθμό αστρογένεσης στον Γαλαξία μας. Παράλληλα μελετώντας την ομάδα Μ81, ανιχνεύτηκε για πρώτη φορά στο οπτικό μέρος του φάσματος, σκόνη στην περιοχή μεταξύ των γαλαξιών. Η μελέτη βασίζεται στην σύγκριση του δείκτη χρώματος των γαλαξιών υποβάθρου, των υποψηφίων περιοχών, με τον δείκτη χρώματος γαλαξιών υποβάθρου σε περιοχές που είναι απομακρυσμένες από την ομάδα Μ81, και αποτελούν πεδία ελέγχου. Η συστηματική ερύθρωση που παρουσίαζαν οι γαλαξίες υποβάθρου στις περιοχές πλησίον της ομάδας Μ81 μπορεί να ερμηνευτεί μόνο με την παρουσία μεγάλων ποσοτήτων σκόνης που εμπεριέχονται στο μεσογαλαξιακό χώρο. Η ποσότητα της σκόνης στις περιοχές αυτές υπολογίστηκε ότι είναι περίπου 50 εκατομμύρια ηλιακές μάζες, όσο δηλαδή και η σκόνη που διαθέτει ένας τυπικός σπειροειδής γαλαξίας. Η προέλευση της σκόνης πιθανολογείται ότι οφείλεται σε ένα μέλος της ομάδας (τον γαλαξία Μ82), ο οποίος είναι ένας γαλαξίας με περιοχές έντονης αστρογένεσης και εκτοξεύει μεγάλες ποσότητες σκόνης στο μεσογαλαξιακό χώρο ή στις παλιρροϊκές δυνάμεις που αναπτύχθηκαν κατά την αλληλεπίδραση των γαλαξιών (που έγινε πριν από 200 εκατομμύρια χρόνια) και εκτόξευσαν στον μεσογαλαξιακό χώρο τεράστιες ποσότητες αερίου και μαζί με αυτό και σκόνη. Οι προβλέψεις για την ύπαρξη σκόνης στις περιοχές αυτές, επιβεβαιώθηκε πρόσφατα από τις υπέρυθρες εικόνες που λήφθηκαν από το διαστημικό τηλεσκόπιο Herschel. / This thesis is based on deep optical CCD images which large have been obtained in the light of Hα+[N II], [O III] and [S II]. The resulting mosaic covers an area of 1.4º ´ 1.0º, where filamentary and diffuse emission was discovered, suggesting the existence of more than one supernova remnants (SNRs) in the area. Deep long slit spectra were also taken at eight different regions. Both the flux calibrated images and the spectra show that the emission of the filamentary structures originates from shock-heated gas, while photo-ionization mechanism is responsible for the diffuse emission. In most case, the optical emission is found to be well correlated with the radio at 1420 MHz and 4850 MHz, suggesting their association. The presence of the [O III] 5007 emission line in one of the candidate SNRs suggests shock velocities into the interstellar "clouds" of >100 Km/s, while the absence in the other indicates slower shock velocities. For all candidate remnants the [S II] λλ 6716/6731 ratio indicates electron densities below 270 cm-3, while the Hα emission has been measured to be between 0.6 to 41´10-17 erg s-1 cm-2 arcsec-2. The detected optical emission could be part of a number of supernovae explosions and the possibility that it is within an OB association can not be ruled out. It will then be the first optical discovery of SRNs within a bubble or superbubble in our Galaxy. Further, the study of those areas, also provides information for the star formation history of the Galaxy. Galactic dust constitutes approximately half of the elements more massive than helium produced in stellar nucleosynthesis. Notwithstanding the formation of dust grains in the dense, cool atmospheres of late-type stars, there still remain huge uncertainties concerning the origin and fate of galactic stardust. In this Letter, we identify the intergalactic medium (i.e., the region between gravitationally bound galaxies) as a major sink for galactic dust. We discover a systematic shift in the color of background galaxies viewed through the intergalactic medium of the nearby M81 group. This reddening coincides with atomic, neutral gas previously detected between the group members. The dust–to–H I mass ratio is high (1/20) compared to that of the solar neighborhood (1/120), suggesting that the dust originates from the center of one or more of the galaxies in the group. Indeed, M82, which is known to be ejecting dust and gas in a starburst-driven superwind, is cited as the probable main source. Εξωγαλαξιακή σκόνη 523.844 65 Supernova remnants Intergalactic medium dust
135	Host stellar population properties and the observational selection function of type Ia supernovae Johnson, Elsa M., 1971- 09 1900 (has links) xlix, 348 p. : ill. (some col.) A print copy of this thesis is available through the UO Libraries. Search the library catalog for the location and call number. / Supernovae Ia are viable standard candles for measuring cosmological distances because of their enormous light output and similar intrinsic brightness. However, dispersion in intrinsic brightness casts doubt on the overall reliability of supernovae as cosmological distance indicators. Moreover, as shown in this thesis, the dependence of peak brightness on host galaxy properties significantly contributes to this dispersion. As a result, there is good reason to doubt that the nearby sample of supernovae Ia is identical to the distant samples, which occur in host galaxies that are billions of years younger. This study explores the validity of supernovae Ia as standard candles by examining regions of nearby galaxies that hosted supernovae and modeling their observational selection function. The approach is two-fold. First, photometry is performed on the stellar population environment of supernovae to characterize that region as a function of supernova type. Then, the observational selection function is simulated to determine the true supernovae production rate of the z < 0.1 redshift limit. We find that, on average, type Ia events occur in redder and older populations; underluminous supernovae Ia occur in regions that seem to be preferentially dusty, whereas normal Ia coming from the same galaxy type occur in a wide range of extinction environments. Furthermore, redder peak colors correspond to redder underlying population colors. This finding implies that dust extinction effects can cause systematic errors in the luminosity calibration of Ia events Finally, a single supernova rate does not adequately describe all supernovae Ia within z < 0.1. A rate of 0.25 SNu describes the population up to z < 0.03, and a much smaller rate, 0.1 SNu or less, describes supernovae past this distance. This finding indicates that observed supernova rates per galaxy remain biased by sample selection effects and that the intrinsic rate is likely uncertain by a factor of 2 to 3. / Committee in charge: Raymond Frey, Chairperson, Physics; James Imamura, Member, Physics; Gregory Bothun, Member, Physics; Stephen Hsu, Member, Physics; James Isenberg, Outside Member, Mathematics Host stellar population Observational selection function Supernovae la Standard candle Supernova Astrophysics Astronomy
136	Modelling star formation and stellar feedback in numerical simulations of galaxy formation Smith, Matthew Carey January 2018 (has links) Remarkable progress has been made over the last few decades in furthering our understanding of the growth of cosmic structure. Nonetheless, there remains a great deal of uncertainty regarding the precise details of the complex baryonic physics that regulate galaxy formation. Any theory of star formation in galaxies must encompass the radiative cooling of gas into dark matter haloes, the formation of a turbulent, multiphase interstellar medium (ISM), the efficiency with which molecular gas is able to collapse into cores and ultimately stars, and the subsequent interaction of those stars with the gas through ionizing radiation, winds and supernova (SN) explosions. Given the highly non-linear nature of the problem, numerical simulations provide an invaluable tool with which to study galaxy formation. Yet, even with contemporary computational resources, the inherently large dynamical range of spatial scales that must be tackled makes the development of such models extremely challenging, inevitably leading to the adoption of `subgrid' approximations at some scale. In this thesis, I explore new methods of incorporating the physics of star formation and stellar feedback into high resolution hydrodynamic simulations of galaxies. I first describe a new implementation of star formation and SN feedback that I have developed for the state-of-the-art moving mesh code Arepo. I carry out a detailed study into various classes of subgrid SN feedback schemes commonly adopted in the literature, including injections of thermal and/or kinetic energy, two parametrizations of delayed cooling feedback and a 'mechanical' feedback scheme that injects the appropriate amount of momentum depending on the relevant scale of the SN remnant (SNR) resolved. All schemes make use of individually time-resolved SN events. Adopting isolated disk galaxy setups at different resolutions, with the highest resolution runs reasonably resolving the Sedov-Taylor phase of the SNR, I demonstrate that the mechanical scheme is the only physically well-posed method of those examined, is efficient at suppressing star formation, agrees well with the Kennicutt-Schmidt relation and leads to converged star formation rates and galaxy morphologies with increasing resolution without fine tuning any parameters. However, I find that it is difficult to produce outflows with high enough mass loading factors at all but the highest resolution. I discuss the various possible solutions to this effect, including improved modelling of star formation. Moving on to a more self-consistent setup, I carry out a suite of cosmological zoom-in simulations of low mass haloes at very high resolution, performed to z = 4, to investigate the ability of SN feedback models to produce realistic galaxies. The haloes are selected in a variety of environments, ranging from voids to crowded locations. In the majority of cases, SN feedback alone has little impact at early times even in low mass haloes ($\sim10^{10}\,\mathrm{M_\odot}$ at z = 0). This appears to be due largely to the build up of very dense gas prior to SN events, suggesting that other mechanisms (such as other stellar feedback processes) are required to regulate ISM properties before SNe occur. The effectiveness of the feedback also appears to be strongly dependent on the merger history of the halo. Finally, I describe a new scheme to drive turbulence in isolated galaxy setups. The turbulent structure of the ISM very likely regulates star formation efficiencies on small scales, as well as affecting the clustering of SNe. The large range of potential drivers of ISM turbulence are not fully understood and are, in any case, unlikely to arise ab initio in a whole galaxy simulation. I therefore neglect these details and adopt a highly idealised approach, artificially driving turbulence to produce an ISM structure of my choice. This enables me to study the effects of a given level of ISM turbulence on global galaxy properties, such as the fragmentation scale of the disk and the impact on SN feedback efficiencies. I demonstrate this technique in the context of simulations of isolated dwarfs, finding that moderate levels of turbulent driving in combination with SN feedback can produce a steady-state of star formation rates and global galaxy properties, rather than the extremely violent SN feedback that is produced by a rapidly fragmenting disk.
137	Identifying Explosive Transients and Implications for Gravitational Wave Followup January 2017 (has links) abstract: High-energy explosive phenomena, Gamma-Ray Bursts (GRBs) and Supernovae (SNe), provide unique laboratories to study extreme physics and potentially open up the new discovery window of Gravitational-wave astronomy. Uncovering the intrinsic variability of GRBs constrains the size of the GRB emission region, and ejecta velocity, in turn provides hints on the nature of GRBs and their progenitors. We develop a novel method which ties together wavelet and structure-function analyses to measure, for the first time, the actual minimum variability timescale, Delta t_min, of GRB light curves. Implementing our technique to the largest sample of GRBs collected by Swift and Fermi instruments reveals that only less than 10% of GRBs exhibit evidence for variability on timescales below 2 ms. Investigation on various energy bands of the Gamma-ray Burst Monitor (GBM) onboard Fermi shows that the tightest constraints on progenitor radii derive from timescales obtained from the hardest energy channel of light curves (299--1000 keV). Our derivations for the minimum Lorentz factor, Gamma_min, and the minimum emission radius, R = 2c Gamma_min^2 Delta t_min / (1+z), find Gamma < 400 which imply typical emission radii R ~ 1 X 10^14 cm for long-duration GRBs and R ~ 3 X 10^13 cm for short-duration GRBs (sGRBs). I present the Reionization and Transients InfraRed (RATIR) followup of LIGO/Virgo Gravitational-wave events especially for the G194575 trigger. I show that expanding our pipeline to search for either optical riZ or near-infrared YJH detections (3 or more bands) should result in a false-alarm-rate ~1% (one candidate in the vast 100 deg^2 LIGO error region) and an efficiency ~90%. I also present the results of a 5-year comprehensive SN search by the Palomar Transient Factory aimed to measure the SN rates in the local Luminous Infrared Galaxies. We find that the SN rate of the sample, 0.05 +/- 0.02 1/yr (per galaxy), is consistent with that expected from the theoretical prediction, 0.060 +/- 0.002 1/yr (per galaxy). / Dissertation/Thesis / Doctoral Dissertation Astrophysics 2017 Astrophysics Astronomy Physics electromagnetic counterparts gamma-ray burst gravitational waves intrinsic variability LIRGs Supernova rate
138	Neutrinos de supernova / Supernova neutrinos Torres, Fernando Rossi, 1982- 16 August 2018 (has links) Orientadores: Marcelo Moraes Guzzo, Pedro Cunha de Holanda / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Física Gleb Wataghin / Made available in DSpace on 2018-08-16T08:24:00Z (GMT). No. of bitstreams: 1 Torres_FernandoRossi_D.pdf: 6051875 bytes, checksum: 56888c02ccce0616320cd185ab5d3267 (MD5) Previous issue date: 2010 / Resumo: Neutrinos de supernova são ferramentas fundamentais, tanto para se entender o mecanismo de explosão de supernovas e formação de núcleos pesados além do ferro, assim como para determinar propriedades ainda desconhecidas e especulativas na física de oscilação de neutrinos, como a existência de neutrinos estéreis e neutrinos com massa variável, modelo este usado como uma das possíveis explicações para o fenômeno de expansão do universo. Outra informação valiosa, que podemos extrair dos neutrinos de supernova, é o limite imposto na massa absoluta dos neutrinos. Para atingir tais objetivos é fundamental termos uma eficiente detecção e também fazermos uma análise estatística mais completa através de uma verossimilhança correta dos próximos eventos de neutrinos de uma futura explosão galática de supernova para que possamos testar modelos de emissão de neutrinos associados ao mecanismo de explosão / Abstract: Supernova neutrinos are fundamental tools both to understand the mechanism of supernova explosion and formation of heavy nuclei beyond iron, as well as to determine yet unknown and speculative properties in the physics of neutrino oscillation, as the existence of sterile neutrinos and neutrinos with variable mass, which is used as a possible explanation for the phenomenona of expansion of the universe. Another valuable information that we can draw from the supernova neutrinos is the limit imposed on the absolute mass of neutrinos. To achieve these goals is essential to have an efficient detection of upcoming neutrino events from a future galactic supernova explosion and also do a more complete statistical analysis through a correct likelihood, testing, for example, models of neutrino emission associated with the explosion mechanism / Doutorado / Física das Particulas Elementares e Campos / Doutor em Ciências Neutrinos Supernova (Estrela) Massa (Física) Oscilações Verossimilhança (Estatística) Neutrinos Supernovae Mass (Physics) Oscillations Likelihood (Statistics)
139	X-Ray Measurements of the Particle Acceleration Properties at Inward Shocks in Cassiopeia A Sato, Toshiki, Katsuda, Satoru, Morii, Mikio, Bamba, Aya, Hughes, John P., Maeda, Yoshitomo, Ishida, Manabu, Fraschetti, Federico 22 January 2018 (has links) We present new evidence that the bright nonthermal X-ray emission features in the interior of the Cassiopeia A supernova remnant are caused by inward-moving shocks, based on Chandra and NuSTAR observations. Several bright inward-moving filaments were identified using monitoring data taken by Chandra in 2000-2014. These inward-moving shock locations are nearly coincident with hard X-ray (15-40 keV) hot spots seen by NuSTAR. From proper-motion measurements, the transverse velocities were estimated to be in the range of similar to 2100-3800 km s(-1) for a distance of 3.4 kpc. The shock velocities in the frame of the expanding ejecta reach values of similar to 5100-8700 km s(-1), which is slightly higher than the typical speed of the forward shock. Additionally, we find flux variations (both increasing and decreasing) on timescales of a few years in some of the inward-moving shock filaments. The rapid variability timescales are consistent with an amplified magnetic field of B similar to 0.5-1 mG. The high speed and low photon cut-off energy of the inward-moving shocks are shown to imply a particle diffusion coefficient that departs from the Bohm regime (k(0) = D-0/D-0,D-Bohm similar to 3-8) for the few simple physical configurations we consider in this study. The maximum electron energy at these shocks is estimated to be similar to 8-11 TeV, which is smaller than the values of similar to 15-34 TeV that were inferred for the forward shock. Cassiopeia A is dynamically too young for its reverse shock to appear to be moving inward in the observer frame. We propose instead that the inward-moving shocks are a consequence of the forward shock encountering a density jump of 5-8 in the surrounding material. acceleration of particles ISM: supernova remnants supernovae: individual (Cassiopeia A) X-rays: ISM
140	The Circumstellar Environment of Type Ia Supernovae Ferretti, Raphael January 2017 (has links) Type Ia supernovae (SNe Ia) have proven to be extremely useful for measuring cosmological distances and were used for the discovery of the accelerated expansion of the universe. Although thousands of SNe Ia have been observed to date, many questions surrounding the physics of the explosions and the nature of their progenitor systems remain unanswered. An notable property of many SNe Ia is the relation between extinction due to dust and their colour. For example SN 2014J, the nearest SN Ia in recent years, has an extinction relation which would be very unusual to observe in the Milky Way. One possible explanation to the peculiar extinction could be the presence of circumstellar (CS) dust surrounding the explosions. Incidentally, some proposed progenitor models of SNe Ia suggest that the explosions are surrounded by shells of matter, which could account for the unusual extinction. CS gas would be ionised, if it is exposed to the intense ultraviolet (UV) radiation of a SN Ia. The research presented in this thesis focuses on the search for CS gas by observing the effects of photoionisation on absorption lines commonly detected in optical spectra. Simple models suggest that the frequently studied sodium doublet (Na I D) should significantly decrease or even disappear if the gas is in the CS environment. Conversely, the absence of variations implies that the absorbing gas clouds must be far from the explosion, in the interstellar medium (ISM). To date, few SNe Ia have been shown to have variable absorption lines, to which we have added another case with SN 2013gh. Yet, we have also shown that most observations searching for variable absorption lines have been taken at too late phases, when most CS gas will have already been ionised. Setting out to obtain the earliest possible coverage of a SN Ia with high-resolution spectra, we have been able to set strong limits on the presence of CS gas surrounding SN 2017cbv. Along with evidence from other observational methods, these results have shown that there is little matter in the CS environments of SNe Ia, suggesting that the peculiar extinction likely results from the dust properties of their host galaxy ISM. Although the progenitor question cannot be resolved by these observations, nondetections of CS gas point to models which do not deposit large amounts of matter in their surroundings. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 5: Submitted.</p> Type Ia supernovae extinction supernova cosmology Astronomy, Astrophysics and Cosmology Astronomi, astrofysik och kosmologi

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