Data di Pubblicazione:
2021
Abstract:
In this work, we present an investigation of the wind in the solar corona that has been initiated by observations of the resonantly scattered
ultraviolet emission of the coronal plasma obtained with UVCS-SOHO, designed to measure the wind outflow speed by applying Doppler dimming
diagnostics. Metis on Solar Orbiter complements the UVCS spectroscopic observations that were performed during solar activity cycle 23 by
simultaneously imaging the polarized visible light and the Hi Lyman- corona in order to obtain high spatial and temporal resolution maps of the
outward velocity of the continuously expanding solar atmosphere. The Metis observations, taken on May 15, 2020, provide the first Hi Lyman-
images of the extended corona and the first instantaneous map of the speed of the coronal plasma outflows during the minimum of solar activity and
allow us to identify the layer where the slow wind flow is observed. The polarized visible light (580–640 nm) and the ultraviolet Hi Ly (121.6 nm)
coronal emissions, obtained with the two Metis channels, were combined in order to measure the dimming of the UV emission relative to a static
corona. This eect is caused by the outward motion of the coronal plasma along the direction of incidence of the chromospheric photons on the
coronal neutral hydrogen. The plasma outflow velocity was then derived as a function of the measured Doppler dimming. The static corona UV
emission was simulated on the basis of the plasma electron density inferred from the polarized visible light. This study leads to the identification,
in the velocity maps of the solar corona, of the high-density layer about 10 wide, centered on the extension of a quiet equatorial streamer present
at the east limb – the coronal origin of the heliospheric current sheet – where the slowest wind flows at about 160 18 km s1 from 4 R to 6 R.
Beyond the boundaries of the high-density layer, the wind velocity rapidly increases, marking the transition between slow and fast wind in the
corona.
ultraviolet emission of the coronal plasma obtained with UVCS-SOHO, designed to measure the wind outflow speed by applying Doppler dimming
diagnostics. Metis on Solar Orbiter complements the UVCS spectroscopic observations that were performed during solar activity cycle 23 by
simultaneously imaging the polarized visible light and the Hi Lyman- corona in order to obtain high spatial and temporal resolution maps of the
outward velocity of the continuously expanding solar atmosphere. The Metis observations, taken on May 15, 2020, provide the first Hi Lyman-
images of the extended corona and the first instantaneous map of the speed of the coronal plasma outflows during the minimum of solar activity and
allow us to identify the layer where the slow wind flow is observed. The polarized visible light (580–640 nm) and the ultraviolet Hi Ly (121.6 nm)
coronal emissions, obtained with the two Metis channels, were combined in order to measure the dimming of the UV emission relative to a static
corona. This eect is caused by the outward motion of the coronal plasma along the direction of incidence of the chromospheric photons on the
coronal neutral hydrogen. The plasma outflow velocity was then derived as a function of the measured Doppler dimming. The static corona UV
emission was simulated on the basis of the plasma electron density inferred from the polarized visible light. This study leads to the identification,
in the velocity maps of the solar corona, of the high-density layer about 10 wide, centered on the extension of a quiet equatorial streamer present
at the east limb – the coronal origin of the heliospheric current sheet – where the slowest wind flows at about 160 18 km s1 from 4 R to 6 R.
Beyond the boundaries of the high-density layer, the wind velocity rapidly increases, marking the transition between slow and fast wind in the
corona.
Tipologia CRIS:
01.01 - Articolo in rivista
Keywords:
Sun: corona – solar wind – Sun: UV radiation
Elenco autori:
Romoli, M.; Antonucci, E.; Andretta, V.; Capuano, G. E.; Da Deppo, V.; De Leo, Y.; Downs, C.; Fineschi, S.; Heinzel, P.; Landini, F.; Liberatore, A.; Naletto, G.; Nicolini, G.; Pancrazzi, M.; Sasso, C.; Spadaro, D.; Susino, R.; Telloni, D.; Teriaca, L.; Uslenghi, M.; Wang, Y. -M.; Bemporad, A.; Capobianco, G.; Casti, M.; Fabi, M.; Frassati, F.; Frassetto, F.; Giordano, S.; Grimani, C.; Jerse, G.; Magli, E.; Massone, G.; Messerotti, M.; Moses, D.; Pelizzo, M. -G.; Romano, P.; Schühle, U.; Slemer, A.; Stangalini, M.; Straus, T.; Volpicelli, C. A.; Zangrilli, L.; Zuppella, P.; Abbo, L.; Auchère, F.; Aznar Cuadrado, R.; Berlicki, A.; Bruno, R.; Ciaravella, A.; D’Amicis, R.; Lamy, P.; Lanzafame, A.; Malvezzi, A. M.; Nicolosi, P.; Nisticò, G.; Peter, H.; Plainaki, C.; Poletto, L.; Reale, F.; Solanki, S. K.; Strachan, L.; Tondello, G.; Tsinganos, K.; Velli, M.; Ventura, R.; Vial, J. -C.; Woch, J.; Zimbardo, G.
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