dc.description.abstract |
Solar atmosphere is permeated with magnetic fields of various spatial scales
that exhibit dynamics in various temporal scales. Study of so called active regions
and their magnetic field measurements are of paramount importance in understanding
the solar atmospheric dynamics and energetic events. Although magnetic
field maps of photosphere are produced with great regularity, the same cannot be
said for chromosphere. Unique conditions offered by chromosphere such as being
close to force-free state facilitate better modeling of solar magnetic fields with
chromospheric magnetic field measurements.
Magnetic field measurements at chromospheric heights are relatively challenging
owing to factors such as (1) lower sensitivity of spectral lines to the magnetic
fields, (2) difficulties in modeling the spectral lines, and (3) weaker magnetic field
strength at these heights. In this thesis, we present instrumentation aspects of Solar
Scanning Polarimeter that has been installed at Kodaikanal Tower-tunnel Telescope
of Kodaikanal Solar Observatory to measure the active region magnetic fields
at chromospheric level, using spectropolarimetry and Zeeman diagnostics of Ca II
8542 Ã… spectral line. In chapter 1, magnetic fields of active regions, their properties
and their role in solar dynamics are discussed. Motivation for the thesis to measure
chromospheric magnetic fields is explained.
In chapter 2, design and development of Solar Scanning Polarimeter, and polarimetry
strategy are discussed. Telescope instrumental polarization has been revisited
and a possible way to reduce it has been proposed. Instrument controls and
operating software are briefly described, along with testing of polarization optics.
In chapter 3, polarimetric data acquisition, calibration of the instrument, observations
and corrections for instrumental polarization are presented. Polarimetric
accuracy and sensitivity are estimated to be few times 102 and 103 respectively.
Line-of-sight magnetic field map that is synthesized from corrected Stokes profiles
usingWeak Fields Approximation is presented. Main challenges such as low raster
image resolution due to image motion and difficulty in computing transverse magnetic
field due to low signal-to-noise ratio are addressed. In chapter 4, design, development and testing of Image Stabilization System are described. Its development
is aimed to reduce image motion induced due to telescope system and seeing.
Correlation tracking of sunspot is used to evaluate its performance, and with an acquisition
and correction rate of 563 Hz, closed loop correction bandwidth of 110 Hz
is achieved.
In chapter 5, a pilot study of correlation between observed chromospheric magnetic
field and modeled chromospheric magnetic field (obtained from potential extrapolation
using photospheric magnetograms) in the active regions is discussed.
In this context, probable formation height of chromospheric spectral line (Ca II
8542 Ã…) in the active regions is indicated. In chapter 6, thesis is summarized and
future scope and needs are outlined. |
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