146 research outputs found
Solar slow magneto-acoustic-gravity waves: an erratum correction and a revisited scenario
Slow waves are commonly observed on the entire solar atmosphere. Assuming a
thin flux tube approximation, the cut-off periods of slow-mode
magneto-acoustic-gravity waves that travel from the photosphere to the corona
were obtained in Costa et al. (2018). In that paper, however, a typo in the
specific heat coefficient at constant pressure value led to an
inconsistency in the cut-off calculation, which is only significant at the
transition region. Due to the abrupt temperature change in the region, a change
of the mean atomic weight (by a factor of approximately two) also occurs, but
is often overlooked in analytical models for simplicity purposes. In this
paper, we revisit the calculation of the cut-off periods of
magneto-acoustic-gravity waves in Costa et al. (2018) by considering an
atmosphere in hydrostatic equilibrium with a temperature profile, with the
inclusion of the variation of the mean atomic weight and the correction of the
inconsistency aforementioned. In addition, we show that the cut-off periods
obtained analytically are consistent with the corresponding periods measured in
observations of a particular active region.Comment: 12 pages, 7 figures. MNRA
Oscillations in the wake of a flare blast wave
Oscillations of coronal loops in the Sun have been reported in both imaging
and spectral observations at the onset of flares. Images reveal transverse
oscillations, whereas spectra detect line-of-sight velocity or Doppler-shift
oscillations. The Doppler-shift oscillations are commonly interpreted as
longitudinal modes. Our aim is to investigate the relationship between loop
dynamics and flows seen in TRACE 195\AA images and Doppler shifts observed by
SUMER in Si III 1113.2\AA and Fe XIX 1118.1\AA at the time of a C.8-class limb
flare and an associated CME. We carefully co-aligned the sequence of TRACE 195
\AA images to structures seen in the SUMER Si III, Ca X,and Fe XIX emission
lines. Additionally, H-alpha observations of a lifting prominence associated
with the flare and the coronal mass ejection (CME) are available in three bands
around 6563.3 \AA . They give constraints on the timing and geometry.
Large-scale Doppler-shift oscillations in Fe XIX and transverse oscillations in
intensity images were observed over a large region of the corona after the
passage of a wide bright extreme-ultraviolet (EUV) disturbance, which suggests
ionization, heating, and acceleration of hot plasma in the wake of a blast
wave.Comment: 4 pages, 6 figures Astronomy & Astrophysics (accepted
Solar prominences line profiles
A numerical code to calculate the line profiles for different elements present in the solar atmosphere was developed for the particular case of solar prominences. The objective is to compare the calculated with the observed profiles in order to limit the range of variation of the physical parameters, as temperature, pressure, electronic density, total density and turbulence velocity, which characterize these phenomena.Asociación Argentina de Astronomí
Propagating waves in polar coronal holes as seen by SUMER and EIS
To study the dynamics of coronal holes and the role of waves in the
acceleration of the solar wind, spectral observations were performed over polar
coronal hole regions with the SUMER spectrometer on SoHO and the EIS
spectrometer on Hinode. Using these observations, we aim to detect the presence
of propagating waves in the corona and to study their properties. The
observations analysed here consist of SUMER spectra of the Ne VIII 770 A line
(T = 0.6 MK) and EIS slot images in the Fe XII 195 A line (T = 1.3 MK). Using
the wavelet technique, we study line radiance oscillations at different heights
from the limb in the polar coronal hole regions. We detect the presence of long
period oscillations with periods of 10 to 30 min in polar coronal holes. The
oscillations have an amplitude of a few percent in radiance and are not
detectable in line-of-sight velocity. From the time distance maps we find
evidence for propagating velocities from 75 km/s (Ne VIII) to 125 km/s (Fe
XII). These velocities are subsonic and roughly in the same ratio as the
respective sound speeds. We interpret the observed propagating oscillations in
terms of slow magneto-acoustic waves. These waves can be important for the
acceleration of the fast solar wind.Comment: 5 pages, 7 figures Accepted as Astronomy and Astrophysics Lette
2D and 3D Polar Plume Analysis from the Three Vantage Positions of STEREO/EUVI A, B, and SOHO/EIT
Polar plumes are seen as elongated objects starting at the solar polar
regions. Here, we analyze these objects from a sequence of images taken
simultaneously by the three spacecraft telescopes STEREO/EUVI A and B, and
SOHO/EIT. We establish a method capable of automatically identifying plumes in
solar EUV images close to the limb at 1.01 - 1.39 R in order to study their
temporal evolution. This plume-identification method is based on a multiscale
Hough-wavelet analysis. Then two methods to determined their 3D localization
and structure are discussed: First, tomography using the filtered
back-projection and including the differential rotation of the Sun and,
secondly, conventional stereoscopic triangulation. We show that tomography and
stereoscopy are complementary to study polar plumes. We also show that this
systematic 2D identification and the proposed methods of 3D reconstruction are
well suited, on one hand, to identify plumes individually and on the other
hand, to analyze the distribution of plumes and inter-plume regions. Finally,
the results are discussed focusing on the plume position with their
cross-section area.Comment: 22 pages, 10 figures, Solar Physics articl
Large non-radial propagation of a coronal mass ejection on 2011 January 24
Understanding the deflection of coronal mass ejections (CMEs) is of great interest to the space weather community because of their implications for improving the prediction of CME. This paper aims to shed light into the effects of the coronal magnetic field environment on CME trajectories. We analyze the influence of the magnetic environment on the early development of a particular CME event. On 2011 January 24 an eruptive filament was ejected in association with a CME that suffered a large deflection from its source region and expected trajectory. We characterize the 3D evolution of the prominence material using the tie-pointing/triangulation reconstruction technique on EUV and white-light images. To estimate the coordinates in 3D space of the apex of the CME we use a forward-modeling technique that reproduces the large-scale structure of the flux rope-like CME, the Graduated Cylindrical Shell model. We found that the deflection amounts to 42° in latitude and 20° in longitude and that most of it occurs at altitudes below 4R⊙. Moreover, we found a non-negligible deflection at higher altitudes. Combining images of different wavelengths with the extrapolated magnetic field obtained from a potential field source surface model we confirm the presence of two magnetic structures near the erupting event. The magnetic field environment suggests that field lines from the southern coronal hole act as a magnetic wall that produces the large latitudinal deflection; while a nearby pseudostreamer and a northward extension of the southern coronal hole may be responsible for the eastward deflection of the CME.Fil: Cécere, Mariana Andrea. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Córdoba. Instituto de Astronomía Teórica y Experimental. Universidad Nacional de Córdoba. Observatorio Astronómico de Córdoba. Instituto de Astronomía Teórica y Experimental; ArgentinaFil: Sieyra, María Valeria. Universidad Tecnológica Nacional; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Cremades Fernandez, Maria Hebe. Universidad Tecnológica Nacional; Argentina. Consejo Nacional de Investigaciones Científicas y Técnicas; ArgentinaFil: Mierla, M.. Institute of Geodynamics of the Romanian Academy; BélgicaFil: Sahade, Abril. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Córdoba. Instituto de Astronomía Teórica y Experimental. Universidad Nacional de Córdoba. Observatorio Astronómico de Córdoba. Instituto de Astronomía Teórica y Experimental; ArgentinaFil: Stenborg, G.. Spece Sciences División. Naval Research Laboratory; Estados UnidosFil: Costa, A.. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Científico Tecnológico Conicet - Córdoba. Instituto de Astronomía Teórica y Experimental. Universidad Nacional de Córdoba. Observatorio Astronómico de Córdoba. Instituto de Astronomía Teórica y Experimental; ArgentinaFil: West, M. J.. Royal Observatory Of Belgium; BélgicaFil: D'Huys, E.. Royal Observatory Of Belgium; Bélgic
- …