Abstract
Abstract. We present a broad concept for the build-up to eruptive solar events which needs to be tested in future observational and theoretical research. In this concept an eruptive solar event consists of a coronal mass ejection, a filament eruption, a cavity around the filament, and a flare. In our picture, the initial energy source must be external to this eruptive system but also feed into it. Among all eruptive events the common denominator is a filament channel with canceling magnetic fields along a primary polarity reversal boundary. We find that magnetic reconnection at or close to the photosphere is the only interpretation of canceling fields to date that is consistent with observations of filament channels. This reconnection serves to transfer magnetic flux from the photosphere into the chromosphere and corona along polarity reversal boundaries and concurrently initiates the building of a filament channel. Magnetic flux, in excess of that needed to sustain the filament channel, goes into building a filament magnetic field that is always aligned with the polarity reversal boundary and the channel magnetic field. The filament magnetic field remains separated from overarching coronal magnetic fields by the magnetic field of the cavity. The magnetic flux being transported upward from the photosphere/chromosphere carries streams of plasma into the corona along the filament magnetic field. However, the flowing and counterstreaming filament mass also slowly drains out of the field and thereby leaves behind new strands of cavity magnetic field with little or no associated mass. When the build-up of magnetic pressure in the filament and cavity magnetic fields exceeds that of the overlying coronal loops, the coronal loops, the filament and the cavity together begin an observable slow rise which can last a few hours to many days before rapid onset and ejection with a solar flare. We suggest that this process can be accelerated by any number of external triggering mechanisms which serve as catalysts to cause the impending eruption to happen earlier than it otherwise would occur.
Highlights
The objective in this paper is to present the hypothesis that CMEs are causally linked to the formation, evolution and maintenance of filament channels, filaments, and filament cavity filament magnetic fields
We proceed step by step to present the rationales for how and why CMEs can be linked back to their ultimate energy source in dynamics associated with canceling magnetic fields in the photosphere beneath eruptive events
It is important that the observations show that (1) the motion of the canceling fields are perpendicular to the direction of the polarity reversal boundary and that (2) the local field direction is nearly parallel to the local polarity reversal boundary
Summary
The objective in this paper is to present the hypothesis that CMEs are causally linked to the formation, evolution and maintenance of filament channels, filaments, and filament cavity filament magnetic fields. We proceed step by step to present the rationales for how and why CMEs can be linked back to their ultimate energy source in dynamics associated with canceling magnetic fields in the photosphere beneath eruptive events. We know that erupting filaments, in particular, originate from specific polarity reversal boundaries that are within filament channels (Martin, 1990; Gaizauskas, 1998). We already know they only come from filament channels that have reached maximum development; i.e. have reached maximum magnetic shear along the polarity boundary (Martin, 1998). All of these events, individually and as a system, are located above and around places where the magnetic field changes polar-
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