Abstract
The inner regions of the solar corona from 1–2.5 Rsun are poorly sampled both from the ground and space
telescopes. A solar eclipse reduces the sky scattered background intensity by a factor of about 10,000 and opens a
window to view this region directly. The goal of the Citizen Continental-America Telescopic Eclipse (CATE)
Experiment is to take a 90-minute time sequence of calibrated white-light images of this coronal region using 60
identical telescopes spread from Oregon to South Carolina during the 2017 August 21 total solar eclipse.
Observations that can address questions of coronal dynamics in this region can be collected with rather modest
telescope equipment, but the large dynamic range of the coronal brightness requires careful camera control. The
instruments used for test runs on the Faroe Islands in 2015 and at five sites in Indonesia in 2016 are described.
Intensity calibration of the coronal images is done and compared with previous eclipse measurements from
November & Koutchmy and Bazin et al. The change of coronal brightness with distance from the Sun seen in the
2016 eclipse agrees with observations from the 1991 eclipse, but differ substantially from the 2010 eclipse. The
2015 observations agree with 2016 and 1991 solar radii near the Sun, but are fainter at larger distances. Problems
encountered during these test runs are discussed as well the solutions which will be implemented for the 2017
eclipse experiment
telescopes. A solar eclipse reduces the sky scattered background intensity by a factor of about 10,000 and opens a
window to view this region directly. The goal of the Citizen Continental-America Telescopic Eclipse (CATE)
Experiment is to take a 90-minute time sequence of calibrated white-light images of this coronal region using 60
identical telescopes spread from Oregon to South Carolina during the 2017 August 21 total solar eclipse.
Observations that can address questions of coronal dynamics in this region can be collected with rather modest
telescope equipment, but the large dynamic range of the coronal brightness requires careful camera control. The
instruments used for test runs on the Faroe Islands in 2015 and at five sites in Indonesia in 2016 are described.
Intensity calibration of the coronal images is done and compared with previous eclipse measurements from
November & Koutchmy and Bazin et al. The change of coronal brightness with distance from the Sun seen in the
2016 eclipse agrees with observations from the 1991 eclipse, but differ substantially from the 2010 eclipse. The
2015 observations agree with 2016 and 1991 solar radii near the Sun, but are fainter at larger distances. Problems
encountered during these test runs are discussed as well the solutions which will be implemented for the 2017
eclipse experiment
| Original language | English |
|---|---|
| Number of pages | 7 |
| Journal | Publications of the Astronomical Society of the Pacific |
| Volume | 129 |
| Issue number | 015505 |
| Publication status | Published - 2017 |
| Externally published | Yes |
Keywords
- instrumentation: miscellaneous
- Sun: corona
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