dc.description.abstract |
Core-collapse supernovae (CCSNe) are catastrophic astrophysical phenomena that occur
during the last evolutionary stages of massive stars having initial masses ≳ 8 M⊙. These
catastrophic events play a pivotal role in enriching our Universe with heavy elements
and are also responsible for the birth of Neutron stars and stellar mass Black holes.
Knowledge of the possible progenitors of CCSNe is fundamental to understanding these
transient events. Additionally, the underlying circumstellar environment around possible
progenitors and the physical mechanism powering the light curves of these catastrophic
CCSN events also require careful investigations to unveil their nature. Based on the
spectroscopic observational features, the CCSNe are primarily divided into H-rich and Hdeficient categories. The H-rich CCSNe display unambiguous H-features in their spectra,
while H-deficient CCSNe don’t. Type Ib SNe are a subclass of H-deficient CCSNe that
lack prominent H-features in their spectra but display distinct He-feature.
The research work within the context of the present thesis is an attempt to investigate
the possible progenitors, ambient media around the progenitors, and powering mechanisms
behind the light curve of CCSNe. Particularly, fractional contributions of different elements, including hydrogen, the key element discriminating Type Ib and Type IIb SNe, are
studied in detail. We also employed several powering mechanisms to decipher underlying
physical mechanisms behind Type Ib and Type IIb SNe. We have employed observational
data from several telescopes, state-of-the-art simulation modules, and 1-dimensional hydrodynamic codes for such investigations.
In this thesis, we have investigated the photometric and spectroscopic properties of
two Type Ib CCSNe, namely, SN 2015ap and SN 2016bau. We aim to gain insight into
their possible progenitors, the circumstellar environment surrounding them, and the powering mechanism for their light curve. We have analysed the photometric characteristics
of the CCSNe mentioned above, encompassing their colour evolution, bolometric luminosity, photospheric radius, temperature, and velocity evolution. By analysing their light
curves, we have computed the ejecta mass, synthesised nickel mass, and ejecta kinetic
energy. Thus, the time domain astronomy of CCSNe is crucial to get insight into their
several physical properties. Furthermore, we have modelled the spectra of SN 2015ap and
SN 2016bau at different stages of their development and also compared their spectra with
several other similar SNe. The P Cygni profiles of different lines present in the spectra
are utilised to understand the velocity evolution of several line-emitting regions. The 1-
dimensional stellar modelling of the possible progenitors and the comparison of the results
of synthetic hydrodynamic explosions with actual observations indicate a 12 M⊙ progenitor exploding in a solar metallicity region as the potential progenitor for SN 2015ap. In
contrast, a slightly less massive star exploding in a solar metallicity environment is the
expected progenitor for SN 2016bau. At the pre-SN stage, the mass of the progenitor of
SN 2016bau lies close to the boundary between the SN and a non-SN phase.
Type IIb SNe are another subclass of CCSNe and are thought to bridge the gap between
H-rich and H-deficient CCSNe. At first, their spectra reveal noticeable H-features, but
after a few weeks, the H-features diminish while prominent He-features begin to emerge.
Type Ib/IIb CCSNe progenitors retain no to very small amounts of hydrogen during
their explosions. However, the correct estimation of the amount of hydrogen retained
before explosion by the underlying CCSN progenitor is subjected to contamination by
the uncertainties associated with determining the extinction and distance of the CCSN.
The photometric and spectroscopic investigations of Type IIb CCSNe are necessary to
understand their progenitors, ambient medium, and powering mechanisms. Such analyses
also decipher their link with the H-rich and H-deficient CCSNe.
In the present research work, we have performed the photometric and spectroscopic
investigation of a Type IIb SN 2016iyc. Our findings indicate that SN 2016iyc lies towards the lower end of the distribution compared to similar CCSNe in terms of inherent brightness. The light curve analysis indicates that SN 2016iyc produces a relatively
smaller amount of ejecta mass and suffers low nickel mass production. Based on the
photometric and spectroscopic behaviour of SN 2016iyc, we performed the stellar evolution of models having initial zero-age main-sequence (ZAMS) masses in the range of
9–14 M⊙. The synthetic explosions of ZAMS star models with mass in the range of 12–
13 M⊙ having the pre-SN radius, R0 within (240–300) R⊙, produce bolometric luminosity
light curves and photospheric velocities that match well with actual observations. Additionally, ejecta mass Mej = (1.89–1.93) M⊙, explosion energy Eexp = (0.28–0.35) ×1051 erg,
and MNi < 0.09 M⊙, are in good agreement with observed estimations; thus, SN 2016iyc
probably exploded from a progenitor lying towards the lower mass limits for SNe IIb.
Additional hydrodynamic simulations have also been conducted to investigate the explosions of SN 2016gkg and SN 2011fu, aiming to compare intermediate- and high-luminosity
examples among the extensively studied SNe Type IIb. The results obtained from modelling the potential progenitors and simulating the explosions of SN 2016iyc, SN 2016gkg,
and SN 2011fu reveal a range of progenitor masses for SNe IIb. The range of progenitor
masses for Type IIb SNe identified under the present research work lies well within the
established range of progenitor masses for CCSNe.
After discussing the properties of H-deficient SNe and the behaviour of a Type IIb
SN retaining an intermediate amount of H-envelope, we provide interesting properties of
H-rich and H-deficient SNe together that originate from progenitors, each having a mass
of 25 M⊙ at ZAMS and zero metallicity. CCSNe from massive Population III (Pop III)
stars are thought to have had an enormous impact on the early Universe. The SNe from
Pop III stars were responsible for the initial enrichment of the early Universe with heavy
elements. Pop III stars played a key role in cosmic re-ionization. Thus, the investigations
of the stellar evolution of Pop III stars and resulting SNe are essential. This thesis presents
the results of 1-dimensional stellar evolution simulations of a rotating Pop III star having
an initial mass of 25 M⊙. Starting from ZAMS, the models are evolved until the onset
of core collapse. The rapidly rotating models exhibit violent and intermittent mass loss
episodes following the main sequence stage. Notably, the Pop III models exhibit smaller
pre-SN radii compared to the model with solar metallicity. Further, with models at
the stage of the onset of core collapse, we perform the hydrodynamic simulations of the
resulting SNe. As a consequence of the mass losses due to corresponding rotations and
stellar winds, the resulting SNe span a class from weak H-rich to H-deficient CCSNe. This
analysis demonstrates the substantial influence of initial stellar rotation on the evolution
of massive stars and their resulting transients. Additionally, we observe that the absolute
magnitudes of CCSNe originating from Pop III stars are much fainter compared to the ones
originating from the star with solar metallicity. Based on the outcomes of our simulations,
we conclude that within the range of explosion energies and nickel masses considered,
these transient events exhibit very low luminosities. Consequently, detecting them at high
redshifts would be a significant challenge.
Beyond discussing the CCSNe resulting from progenitors having ZAMS masses of
25 M⊙ or less, we have also studied the stellar evolution of a massive 100 M⊙ ZAMS star
up to the onset of core collapse. Based on initial mass, mass loss rate, rotation and
metallicity, the resulting transient could fall into any category, PISN, PPISN, Type IIPlike SNe, and several H-rich/H-deficient SNe showing ejecta-CSM interaction signatures.
However, in the presented thesis, we have investigated the consequences of a non-rotating
100 M⊙ ZAMS progenitor exploding into Type IIP-like CCSNe. We also have explored the
effect of the variation of explosion energy and nickel mass on the light curves of resulting
CCSNe.
The research work presented here has paved the way for new avenues of exploration
within astronomy and astrophysics. Ultimately, we summarise our significant findings
and discuss the potential prospects. We attempt to highlight the role of observations and simulations in synergistic investigations of transients. The increasing number of progenitor detections in high-resolution pre-explosion images and further refinement of available
state-of-the-art stellar evolution codes would certainly protrude the knowledge of CCSNe. |
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