2018
DOI: 10.1093/mnras/sty1926
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The magnetic field vector of the Sun-as-a-star – II. Evolution of the large-scale vector field through activity cycle 24

Abstract: In the present work, we investigate how the large-scale magnetic field of the Sun, in its three vector components, has evolved during most of cycle 24, from 2010 Jan to 2018 Apr. To filter out the small-scale field of the Sun, present in high-resolution synoptic maps, we use a spherical harmonic decomposition method, which decomposes the solar field in multipoles with different degrees. By summing together the low-multipoles, we reconstruct the large-scale field at a resolution similar to observed stellar magn… Show more

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Cited by 26 publications
(29 citation statements)
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“…This transition of the large-scale dipole field is also seen in the Sun (DeRosa et al 2012;Finley et al 2018). Recent analyses by Vidotto et al (2018) indicate that the solar large-scale field, filtered for the large-scale components, shows a similar trend to that presented in Figs. A.1 and A.2. During epochs 2017.89 and 2018.52 the activity decreases even further, as shown in Fig.…”
Section: Discussionsupporting
confidence: 75%
“…This transition of the large-scale dipole field is also seen in the Sun (DeRosa et al 2012;Finley et al 2018). Recent analyses by Vidotto et al (2018) indicate that the solar large-scale field, filtered for the large-scale components, shows a similar trend to that presented in Figs. A.1 and A.2. During epochs 2017.89 and 2018.52 the activity decreases even further, as shown in Fig.…”
Section: Discussionsupporting
confidence: 75%
“…Figure 4 shows the time-latitude diagrams for the axisymmetric components of magnetic field and vector potential. The time-latitude diagrams of the magnetic field evolution are in agreement with Vidotto et al (2018). The reconstructed potentials disagree with results of Pipin & Pevtsov (2014), who used profiles ofB r from different longitudinal distances from the central meridian to reconstructB φ andĀ r .…”
Section: Resultssupporting
confidence: 63%
“…10). When the Sun is at minimum activity, its large-scale magnetic field is dominated by a dipolar field, whose axis is roughly aligned with the rotation axis (Sanderson et al 2003;DeRosa et al 2012;Vidotto et al 2018a). In this case, the solar wind velocity distribution is organised into a faster stream ( $ 700-800 km/s) emerging from high latitude coronal holes and a slower stream ( $ 400 km/s) around the equatorial plane (McComas et al 1998).…”
Section: Accretion Onto White Dwarfs As Probe Of the Wind Of Secondary Companionmentioning
confidence: 99%
“…In this case, the solar wind velocity distribution is organised into a faster stream ( $ 700-800 km/s) emerging from high latitude coronal holes and a slower stream ( $ 400 km/s) around the equatorial plane (McComas et al 1998). Conversely, at solar maximum, the large-scale magnetic field geometry is more complex, with a dipolar component vanishing and giving rise to higher-order fields, in particular, even-mode components become more important, such as the quadrupole component (DeRosa et al 2012;Vidotto et al 2018a). The solar wind speed in this case has a more complex distribution, as shown in the right panel of Fig.…”
Section: Accretion Onto White Dwarfs As Probe Of the Wind Of Secondary Companionmentioning
confidence: 99%