TY - UNPB
T1 - Exploring the Physics of the Corona with Total Solar Eclipse Observations
AU - Habbal, Shadia Rifai
AU - Cooper, John
AU - Daw, Adrian
AU - Ding, Adalbert
AU - Druckmuller, Miloslav
AU - Esser, Ruth
AU - Johnson, Judd
AU - Morgan, Huw
N1 - eprint arXiv:1108.2323
PY - 2011/8/1
Y1 - 2011/8/1
N2 - This white paper is a call for a concerted effort to support total solar
eclipse observations over the next decade, in particular for the 21
August 2017 eclipse which will traverse the US continent. With the
recent advances in image processing techniques and detector technology,
the time is ripe to capitalize on the unique diagnostic tools available
in the visible and near infrared wavelength range to explore the physics
of the corona. The advantage of coronal emission lines in this
wavelength range, over their extreme ultraviolet counterparts, is (1)
the significant radiative component in their excitation process (in
addition to the collisional excitation), which allows for observations
out to a few solar radii, (2) the higher spectral selectivity available
for imaging, giving well-defined temperature responses for each bandpass
(one line as opposed to many), and (3) the capability of polarization
measurements in a number of spectral lines. Consequently, the evolution
of the thermodynamic and magnetic properties of the coronal plasma can
be explored starting from the solar surface out to a few solar radii,
namely the most important region of the corona where the expansion of
the solar magnetic field and the acceleration of the solar wind occur.
Since the planning of eclipse observations will not be possible without
the invaluable NASA-published total solar eclipse bulletins by Espenak
and Andersen, a call is also made to ensure continued support for these
efforts.
AB - This white paper is a call for a concerted effort to support total solar
eclipse observations over the next decade, in particular for the 21
August 2017 eclipse which will traverse the US continent. With the
recent advances in image processing techniques and detector technology,
the time is ripe to capitalize on the unique diagnostic tools available
in the visible and near infrared wavelength range to explore the physics
of the corona. The advantage of coronal emission lines in this
wavelength range, over their extreme ultraviolet counterparts, is (1)
the significant radiative component in their excitation process (in
addition to the collisional excitation), which allows for observations
out to a few solar radii, (2) the higher spectral selectivity available
for imaging, giving well-defined temperature responses for each bandpass
(one line as opposed to many), and (3) the capability of polarization
measurements in a number of spectral lines. Consequently, the evolution
of the thermodynamic and magnetic properties of the coronal plasma can
be explored starting from the solar surface out to a few solar radii,
namely the most important region of the corona where the expansion of
the solar magnetic field and the acceleration of the solar wind occur.
Since the planning of eclipse observations will not be possible without
the invaluable NASA-published total solar eclipse bulletins by Espenak
and Andersen, a call is also made to ensure continued support for these
efforts.
UR - http://hdl.handle.net/2160/9114
M3 - Working paper
BT - Exploring the Physics of the Corona with Total Solar Eclipse Observations
PB - arXiv
ER -