Atom & cosmos: Plasma corkscrews produce new twist: Latest observation extends debate over solar eruptions

Solar Orbiter is the first space mission observing the solar plasma both in situ and remotely, from a close distance, in and out of the ecliptic. The ultimate goal is to understand how the Sun produces and controls the heliosphere, filling the Solar System and driving the planetary environments. With six remote-sensing and four in-situ instrument suites, the coordination and planning of the operations are essential to address the following four top-level science questions: (1) What drives the solar wind and where does the coronal magnetic field originate?; (2) How do solar transients drive heliospheric variability?; (3) How do solar eruptions produce energetic particle radiation that fills the heliosphere?; (4) How does the solar dynamo work and drive connections between the Sun and the heliosphere? Maximising the mission’s science return requires considering the characteristics of each orbit, including the relative position of the spacecraft to Earth (affecting downlink rates), trajectory events (such as gravitational assist manoeuvres), and the phase of the solar activity cycle. Furthermore, since each orbit’s science telemetry will be downloaded over the course of the following orbit, science operations must be planned at mission level, rather than at the level of individual orbits. It is important to explore the way in which those science questions are translated into an actual plan of observations that fits into the mission, thus ensuring that no opportunities are missed. First, the overarching goals are broken down into specific, answerable questions along with the required observations and the so-called Science Activity Plan (SAP) is developed to achieve this. The SAP groups objectives that require similar observations into Solar Orbiter Observing Plans, resulting in a strategic, top-level view of the optimal opportunities for science observations during the mission lifetime. This allows for all four mission goals to be addressed. In this paper, we introduce Solar Orbiter’s SAP through a series of examples and the strategy being followed.

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Additivity of relative magnetic helicity in finite volumes

Astronomy and Astrophysics ◽

10.1051/0004-6361/202038533 ◽

2020 ◽

Vol 643 ◽

pp. A26

Author(s):

Gherardo Valori ◽

Pascal Démoulin ◽

Etienne Pariat ◽

Anthony Yeates ◽

Kostas Moraitis ◽

...

Keyword(s):

Complex Dynamics ◽

Flux Rope ◽

Dynamical Evolution ◽

Finite Volumes ◽

Magnetic Helicity ◽

Relaxation Processes ◽

Gauge Invariant ◽

Hydrodynamic Evolution ◽

Solar Eruptions ◽

Unified View

Context. Relative magnetic helicity is conserved by magneto-hydrodynamic evolution even in the presence of moderate resistivity. For that reason, it is often invoked as the most relevant constraint on the dynamical evolution of plasmas in complex systems, such as solar and stellar dynamos, photospheric flux emergence, solar eruptions, and relaxation processes in laboratory plasmas. However, such studies often indirectly imply that relative magnetic helicity in a given spatial domain can be algebraically split into the helicity contributions of the composing subvolumes, in other words that it is an additive quantity. A limited number of very specific applications have shown that this is not the case. Aims. Progress in understanding the nonadditivity of relative magnetic helicity requires removal of restrictive assumptions in favor of a general formalism that can be used in both theoretical investigations and numerical applications. Methods. We derive the analytical gauge-invariant expression for the partition of relative magnetic helicity between contiguous finite volumes, without any assumptions on either the shape of the volumes and interface, or the employed gauge. Results. We prove the nonadditivity of relative magnetic helicity in finite volumes in the most general, gauge-invariant formalism, and verify this numerically. We adopt more restrictive assumptions to derive known specific approximations, which yields a unified view of the additivity issue. As an example, the case of a flux rope embedded in a potential field shows that the nonadditivity term in the partition equation is, in general, non-negligible. Conclusions. The nonadditivity of relative magnetic helicity can potentially be a serious impediment to the application of relative helicity conservation as a constraint on the complex dynamics of magnetized plasmas. The relative helicity partition formula can be applied to numerical simulations to precisely quantify the effect of nonadditivity on global helicity budgets of complex physical processes.

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Formation of Magnetic Flux Rope During Solar Eruption. I. Evolution of Toroidal Flux and Reconnection Flux

Frontiers in Physics ◽

10.3389/fphy.2021.746576 ◽

2021 ◽

Vol 9 ◽

Author(s):

Chaowei Jiang ◽

Jun Chen ◽

Aiying Duan ◽

Xinkai Bian ◽

Xinyi Wang ◽

...

Keyword(s):

Magnetic Flux ◽

Early Phase ◽

Flux Rope ◽

Three Dimensions ◽

Bottom Surface ◽

Peak Time ◽

Magnetic Flux Ropes ◽

Twisted Field ◽

Solar Eruptions ◽

Field Lines

Magnetic flux ropes (MFRs) constitute the core structure of coronal mass ejections (CMEs), but hot debates remain on whether the MFR forms before or during solar eruptions. Furthermore, how flare reconnection shapes the erupting MFR is still elusive in three dimensions. Here we studied a new MHD simulation of CME initiation by tether-cutting magnetic reconnection in a single magnetic arcade. The simulation follows the whole life, including the birth and subsequent evolution, of an MFR during eruption. In the early phase, the MFR is partially separated from its ambient field by a magnetic quasi-separatrix layer (QSL) that has a double-J shaped footprint on the bottom surface. With the ongoing of the reconnection, the arms of the two J-shaped footprints continually separate from each other, and the hooks of the J shaped footprints expand and eventually become closed almost at the eruption peak time, and thereafter the MFR is fully separated from the un-reconnected field by the QSL. We further studied the evolution of the toroidal flux in the MFR and compared it with that of the reconnected flux. Our simulation reproduced an evolution pattern of increase-to-decrease of the toroidal flux, which is reported recently in observations of variations in flare ribbons and transient coronal dimming. The increase of toroidal flux is owing to the flare reconnection in the early phase that transforms the sheared arcade to twisted field lines, while its decrease is a result of reconnection between field lines in the interior of the MFR in the later phase.

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SECTION OF OCEANOGRAPHY AND METEOROLOGY: SOLAR ERUPTIONS AND THE WEATHER*

Transactions of the New York Academy of Sciences ◽

10.1111/j.2164-0947.1956.tb00517.x ◽

1956 ◽

Vol 19 (2 Series II) ◽

pp. 138-146 ◽

Cited By ~ 7

Author(s):

Julius London

Keyword(s):

Solar Eruptions

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Numerical Short-Term Solar Activity Forecasting

Proceedings of the International Astronomical Union ◽

10.1017/s1743921318000534 ◽

2017 ◽

Vol 13 (S335) ◽

pp. 243-249 ◽

Cited By ~ 2

Author(s):

Huaning Wang ◽

Yihua Yan ◽

Han He ◽

Xin Huang ◽

Xinghua Dai ◽

...

Keyword(s):

Solar Activity ◽

Magnetic Fields ◽

Solar Atmosphere ◽

Magnetic Energy ◽

Three Dimensional ◽

Active Regions ◽

Short Term ◽

Solar Active Regions ◽

Solar Eruptions ◽

Dimensional Reconstruction

AbstractIt is well known that the energy for solar eruptions comes from magnetic fields in solar active regions. Magnetic energy storage and dissipation are regarded as important physical processes in the solar corona. With incomplete theoretical modeling for eruptions in the solar atmosphere, activity forecasting is mainly supported with statistical models. Solar observations with high temporal and spatial resolution continuously from space well describe the evolution of activities in the solar atmosphere, and combined with three dimensional reconstruction of solar magnetic fields, makes numerical short-term (within hours to days) solar activity forecasting possible. In the current report, we propose the erupting frequency and main attack direction of solar eruptions as new forecasts and present the prospects for numerical short-term solar activity forecasting based on the magnetic topological framework in solar active regions.

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