EGU21-14801
https://doi.org/10.5194/egusphere-egu21-14801
EGU General Assembly 2021
© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

First results from combined EUI and SPICE observations of Lyman lines of Hydrogen and He II

Luca Teriaca1 and the EUI and SPICE Teams*
Luca Teriaca and the EUI and SPICE Teams
  • 1Max Planck Institut für Sonnensystemforschung, Goettingen, Germany (teriaca@mps.mpg.de)
  • *A full list of authors appears at the end of the abstract

The Solar Orbiter spacecraft carries a powerful set of remote sensing instruments that allow studying the solar atmosphere with unprecedented diagnostic capabilities. Many such diagnostics require the simultaneous usage of more than one instrument. One example of that is the capability, for the first time, to obtain (near) simultaneous spatially resolved observations of the emission from the first three lines of the Lyman series of hydrogen and of He II Lyman alpha. In fact, the SPectral Imaging of the Coronal Environment (SPICE) spectrometer can observe the Lyman beta and gamma lines in its long wavelength (SPICE-LW) channel, the High Resolution Lyman Alpha (HRILYA) telescope of the Extreme Ultraviolet Imager (EUI) acquires narrow band images in the Lyman alpha line while the Full Disk Imager (FSI) of EUI can take images dominated by the Lyman alpha line of ionized Helium at 30.4 nm (FSI-304). Being hydrogen and helium the main components of our star, these very bright transitions play an important role in the energy budget of the outer atmosphere via radiative losses and the measurement of their profiles and radiance ratios is a fundamental constraint to any comprehensive modelization effort of the upper solar chromosphere and transition region. Additionally, monitoring their average ratios can serve as a check out for the relative radiometric performance of the two instruments throughout the mission.

Although the engineering data acquired so far are far from ideal in terms of time simultaneity (often only within about 1 h) and line coverage (often only Lyman beta was acquired by SPICE and not always near simultaneous images from all three telescopes are available) the analysis we present here still offers a great opportunity to have a first look at the potential of this diagnostic from the two instruments.

In fact, we have identified a series of datasets obtained at disk center and at various positions at the solar limb that allow studying the Lyman alpha to beta radiance ratio and their relation to He II 30.4 as a function of the position on the Sun (disk center versus limb and quiet Sun versus coronal holes).

EUI and SPICE Teams:

R. Aznar Cuadrado, A. Giunta, T. Grundy, S. Parenti, F. Auchere, J.-C. Vial, A. Fludra, D. Berghmans, M. Carlsson, L. Harra, D. Hassler, D. Long, H. Peter, P. Rochus, U. Schühle, É. Buchlin, M. Caldwell, S. Caminade, C. DeForest, T. Fredvik, S. Gissot, K. Heerlein, M. Janvier, E. Kraaikamp, T. Kucera, D. Müller, W. Schmutz, S. Sidher, P. Smith, K. Stegen, W. Thompson, C. Verbeeck, D. Williams, P. Young

How to cite: Teriaca, L. and the EUI and SPICE Teams: First results from combined EUI and SPICE observations of Lyman lines of Hydrogen and He II, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-14801, https://doi.org/10.5194/egusphere-egu21-14801, 2021.

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