EUV observables of simulated plasmoid-mediated reconnection in the solar corona
{O}. H. F{ae}rder, D. N’obrega-Siverio, M. Carlsson, J. Mart’inez-Sykora
arXiv:2404.07327v1 Announce Type: new
Abstract: Understanding the role of magnetic reconnection in the heating and dynamics of the solar atmosphere requires detailed observational data of any observable aspect of the reconnection process, including small-scale features such as plasmoids. We aim to examine the capability of active and upcoming instruments to detect plasmoids generated by reconnection in the corona including low-density regimes. We used the Bifrost code to perform simulations of plasmoid-mediated reconnection in the corona based on a 2D idealised setup: a fan-spine topology with uniform density including thermal conduction. Through forward-modelling of extreme-ultraviolet (EUV) observables, we checked whether our simulated plasmoids could be detected with the instruments of Solar Dynamics Observatory (SDO) and Solar Orbiter (SO), as well as the upcoming Multi-Slit Solar Explorer (MUSE) and Solar-C missions. Short-lived (10-20 s) small-scale (0.2-0.5 Mm) coronal plasmoids are not resolvable with the Atmospheric Imaging Assembly (AIA) onboard SDO, but could be captured with the Extreme Ultraviolet Imager (EUI) of SO. The spatial and temporal high-resolution planned for the MUSE spectrograph (SG) is adequate to obtain full spectral information of these plasmoids. Detection of 0.8 MK plasmoids in the MUSE/SG 171 {AA} channel should work on full-raster mode in regions with electron densities above 10^9 cm^3 whereas on sit-and-stare mode for lower-density regions. Solar-C could also capture these coronal plasmoids using the EUV High-Throughput Spectroscopic Telescope (EUVST), through rapid changes in Doppler shift and line width in different EUV lines caused by plasmoid motions along the current sheet. With combined spectra of MUSE/SG and Solar-C/EUVST in multiple emission lines, along with high-resolution images from SO/EUI and MUSE/CI, it should be possible to gain new insights about plasmoid formation in the corona.arXiv:2404.07327v1 Announce Type: new
Abstract: Understanding the role of magnetic reconnection in the heating and dynamics of the solar atmosphere requires detailed observational data of any observable aspect of the reconnection process, including small-scale features such as plasmoids. We aim to examine the capability of active and upcoming instruments to detect plasmoids generated by reconnection in the corona including low-density regimes. We used the Bifrost code to perform simulations of plasmoid-mediated reconnection in the corona based on a 2D idealised setup: a fan-spine topology with uniform density including thermal conduction. Through forward-modelling of extreme-ultraviolet (EUV) observables, we checked whether our simulated plasmoids could be detected with the instruments of Solar Dynamics Observatory (SDO) and Solar Orbiter (SO), as well as the upcoming Multi-Slit Solar Explorer (MUSE) and Solar-C missions. Short-lived (10-20 s) small-scale (0.2-0.5 Mm) coronal plasmoids are not resolvable with the Atmospheric Imaging Assembly (AIA) onboard SDO, but could be captured with the Extreme Ultraviolet Imager (EUI) of SO. The spatial and temporal high-resolution planned for the MUSE spectrograph (SG) is adequate to obtain full spectral information of these plasmoids. Detection of 0.8 MK plasmoids in the MUSE/SG 171 {AA} channel should work on full-raster mode in regions with electron densities above 10^9 cm^3 whereas on sit-and-stare mode for lower-density regions. Solar-C could also capture these coronal plasmoids using the EUV High-Throughput Spectroscopic Telescope (EUVST), through rapid changes in Doppler shift and line width in different EUV lines caused by plasmoid motions along the current sheet. With combined spectra of MUSE/SG and Solar-C/EUVST in multiple emission lines, along with high-resolution images from SO/EUI and MUSE/CI, it should be possible to gain new insights about plasmoid formation in the corona.