dc.description.abstract |
Stars form in the densest regions of molecular clouds which are actually gravitationally unstable
cores that resides at the junction of filaments. Before the onset of the gravitational collapse in cores,
the build up of filaments and further substructures takes place. The formation of dense cores and
the filaments is a crucial step in the star formation process. The question involving how the diffuse
gas transforms to dense regions decides the star formation rate and the mass distribution of stars in
molecular clouds. The association of cores with the filaments which turn into cores indicates that
the filaments play a central role in the process of forming stars. However, even with a plethora of
observational and theoretical information available, the role of turbulence, self-gravity and magnetic
fields in the formation of filamentary structures is still a debated topic. Understanding the connection
of the molecular cloud structure with its formation mechanism is crucial in knowing the intricacies of
star formation process.
In this thesis, we investigated the characteristics, dynamics, and the global evolution of filamentary
structures formed in two different scenarios either by isolated star formation or triggered star formation.
In order to characterise observationally the process of filament and dense core formation with different
physical effects in molecular clouds, we studied two regions in detail, L1172/L1174 and L1157/L1158.
These regions are located in Cepheus constellation at higher galactic latitude. The striking difference
between the ongoing star formation activity in both the regions makes them the favourable testbeds
for studying the filaments formation in isolated or clustered sites. We studied each of these regions
by means of large-scale molecular line observations in the range of millimeter or sub-millimetre
wavelengths by choosing tracers sensitive to different density structures in clouds. The results were
complimented with the dust continuum emissions. We first extracted the filaments and cores using
and estimated their geometric properties and further estimated the detailed velocity structure of all
the filaments and cores. The large scale magnetic field morphology was inferred either from ground
based optical polarization or from the Planck polarization maps.
One part of the regions studied, L1172/L1174 resembles the hub-filament morphology. The
presence of intermediate mass star can significantly influence the surrounding gas by interaction of
stellar winds with the neutral molecular cloud. Our detailed characterization of the gas kinematics of
filaments and cores around massive star showed the presence of high velocity gas is affecting the high
density gas. The gas show spectral signatures of expansion or contraction through blue or red-skewed
profiles. We further explored the origin behind the hub-filament morphology of L1172/L1174 complex
by studying the physical conditions of high density gas and its comparison with the dust emission
in the long filament associated to the complex. Our results reveal the presence of velocity gradients
which may be responsible for the accretion of gas towards the high massive core. Based on the
correlation of magnetic field lines with the filament orientation, the same is found to be dynamically
important for the morphology of the filament.
To understand the physical state of gas in the filaments and the cores in L1147/L1158 complex
which is in close proximity to L1172/L1174 and share similar radial velocity and distances but low star
formation efficiency, we studied the molecular line mapping of the whole region at 0.1 km s−1
spectral
resolution. The velocity structure of each of the filament was investigated in detail. The kinematical
information on both the complexes will help in understanding the difference in star formation activity
and testing various theories of turbulent magnetized medium. The large scale gas dynamics in both
the complexes suggest that the filaments indeed preserve the initial condition of star formation.
The next part of the thesis explores the importance of motion of the cloud with the respect the
magnetic fields. We also studied the distribution of core orientation over a sample of molecular clouds
which builds up a link between cloud-scale magnetic field and core orientation. We established the
distribution of offsets between core orientation and motion of the complexes in the galaxy. We also
studied a set of nearby clouds with asymmetric dust emission using magnetic fields using starlight
polarization and the thermal dust emission using Planck and the relative orientation of cores with the
magnetic fields. |
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