麻豆淫院

A research team led by Dr. Shen Jinhua from the Xinjiang Astronomical Observatory (XAO) of the Chinese Academy of Sciences has investigated rapid spatiotemporal vertical electric currents (VECs) during an X-class flare.

The findings, based on high-cadence magnetograms and extreme ultraviolet observations from the Solar Dynamics Observatory (SDO) of NASA, are in The Astrophysical Journal.

Using vector magnetograms from the Helioseismic and Magnetic Imager (HMI) with a time resolution of 135 seconds, along with extreme ultraviolet data from the Atmospheric Imaging Assembly (AIA), the researcher analyzed the spatiotemporal evolution of photospheric VECs during an X1.1-class flare in active region NOAA 11890.

Their aim was to understand how magnetic energy is rapidly dissipated from the reconnection-driven corona to the lower atmosphere using high-cadence magnetograms.

"According to the velocity field map, there obviously exist shearing and converging motion (i.e., oppositely directed flows on the two sides of polarity inversion lines) preceding the flare onset, which are located in the light bridge of the sunspot along the strong polarity inversion lines.

"These observations suggest that the magnetic fields with sheared motions could be accumulating energy before the flare onset, and the initial current density is more likely to originate from photospheric motions," said Dr. Shen.

The spatial configuration of VEC ribbons is always conjugate footprints, and it takes the form of a sigmoid along two sides of the PIL at the beginning of the flare. The researchers confirmed previous results regarding the rapid and simultaneous increase of VECs associated with flares.

The VEC ribbons take the form of a J-shaped configuration, which is expected to be from quasi-separatrix layer magnetic reconnection inside a magnetic flux rope. However, they found that the spatial distribution of photospheric VECs, especially, and its temporal evolution, are closely correlated with the rapid enhancement of horizontal magnetic fields during the flare.

The close correlation is obtained from two observational facts: First, positive and negative VEC ribbons appear at the two opposite edges of the enhanced horizontal magnetic field (B_h) and spread outward along the magnetic polarity inversion line. Second, the two VEC ribbons show a kind of approaching motion toward the center of B_h enhancement.

In contrast, the flaring loops and white-light flare ribbons have an initial contraction and later expansion motion. The results show that the rapid change of magnetic fields related to flares has a predominant role in affecting the spatiotemporal evolution of VECs.

The previous view held that the evolution of the photospheric current ribbons corresponded to the separation movement of the flare ribbons. The observation and calculation results of this study present completely opposite conclusions, providing strong observational evidence for the existing flare theoretical model and current evolution.

The results demonstrate that the rapid movement of the photospheric magnetic field during the flare process leads to the converging movement of the current.

This work provides important insights into the evolution of VEC, in particular reporting the approaching motion of VECs during a flare for the first time.