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The thesis is mainly focused on the modeling of pulsar radio emission and polarization.
The radio emission mechanism of pulsar is not fully understood, because of the lack
of understanding about the kinematical processes involved in pulsar magnetosphere,
radio emission geometry and magnetic field topology obviously. Observation strongly
suggest that pulsar radio emission is a coherent process, as very high energetic emission
with corresponding brightness temperature 10^25 K is taken place from a source with
size around 10 km.
From an astrophysical point of view, pulsars are often characterized as quantum
degenerate stars i.e., neutron star, which is highly magnetized (B = 10^8 − 10^13
G), highly compact rotating object. There has been attributed specific locations or
magnetospheric gaps, for example polar gap, outer gap etc. in literatures, which are demarcated
as the locations exclusively for originating radio emission and X-ray emission
respectively. Polar cap boundary is defined as the footprint of last open magnetic field
lines. On the other hand outer gap is located in a region close to neutron star’s surface
and in between open and closed magnetic field lines. As pulsar is spinning rapidly
with huge magnetic field, it induces large electric field across polar cap region, which
is around 10^12 volt per cm. This huge electric field exceeds the vacuum breakdown
condition and as a result the region above polar cap is filled with charged particles.
Due to huge background magnetic field, the momentum of particles, perpendicular to
magnetic field is dissipated away very quickly and thereafter they continue to accelerate
along the open magnetic field line. As a result of charged particle acceleration due
to movement along curved magnetic field line, curvature radiation photons (gammarays)
are generated. These curvature photons subsequently decay into electron and
positron pairs via cascade process which produce a cloud of secondary charged particles
with Lorentz factor 100-1000. This secondary charged particles are believed to be
responsible for pulsar radio emission.
There have been suggested three processes to explain pulsar radio emission mechanism,
(i) Antenna mechanism, (ii) Relativistic plasma instabilities and (iii) Maser
emission mechanism, whose elaborate descriptions are provided with sufficient details
in chapter 1 and chapter 2. Masers are in fact closely related to plasma instabilities.
Abinitio a generic introduction to radio pulsar is given in chapter 1 with diferent polarization
related properties. Nevertheless the main aim of this thesis is to make a
model by considering collective plasma process and suitably chosen geometry to estimate
radio pulsar brightness temperature theoretically, which is shown in 3rd chapter.
We develop a mechanism for pulsar radio emission which takes into account of the
detailed viewing geometry of pulsars and dipolar magnetic field configuration. By using
a suitably chosen geometry and plasma parameters we derive analytical expressions for
the Stokes parameters of the radiation field in the neutron star centered frame. We
have simulated the pulse profiles based on our analytical formulation. It seems we can
explain the enhanced radiation and most of the diverse polarization properties of radio
pulsars. We have estimated the brightness temperature, which seems to agree with
the observations. The polarization angle predicted by the model is in good agreement
with the rotating vector model. The brightness temperature shows a reasonably good
agreement between theoretically computed values and observation.
In 4th chapter, I have discussed about the power spectra modeling of radio
pulsars by introducing plasma processes such as Stimulated Raman scattering (SRS)
and Stimulated Compton Scattering (SCS). Usually flux of pulsars in radio regime falls
inversely with frequency, with mean value of index lying between -3 to -1. There has
been proposed diferent types of power spectra like simple power law, two segmented
broken power law, log-parabolic etc. It is evident that, two diferent distinct plasma
processes are responsible for generating two segmented broken power law. So in chapter
4 I have used SRS and SCS as potential tools to reproduce power spectra of a few
pulsars theoretically. It seems like about 80% of pulsars exhibit single power law and
rest of the 20% show two segmented broken power law and other types. In chapter
4, I have basically shown how non-linear plasma processes such as SRS and SCS can
be applied to pulsars and reproduce their power spectra in radio regimes theoretically.
In chapter 5, I have investigated the role of SRS on the polarization state of pulsar
radio emission. It is shown that rapid temporal variability of intensity and switching of
polarization state from elliptical to circular, linear and vice-versa can be incorporated
by implementing SRS, under diferent plasma conditions. Apart from that, it is shown
that the efect of SRS is more pronounced in the typical pulsar magnetosphere than
other efects such as Faraday rotation. In chapter 6, all the chapters are summarized
together and merits of the theories in connection to observations are justified with
future implication.
My future plans are to: (1) Make observations of pulsars and their power-law
spectra, (2) Estimate the aberration-retardation (A/R) efects on pulsar spectra, (3)
Study the orthogonal polarization mode (OPM) phenomena. In addition to pulsars,
my other future plans are to study Fast Radio Bursts (FRB). |
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