期刊
ASTROPHYSICAL JOURNAL
卷 577, 期 1, 页码 487-495出版社
IOP PUBLISHING LTD
DOI: 10.1086/342169
关键词
MHD; Sun : flares; Sun : magnetic elds
In the framework of a refined Kolmogorov hypothesis, the scaling behavior of the B-2-component of the photospheric magnetic field is analyzed and compared with flaring activity in solar active regions. We use Solar and Heliospheric Observatory Michelson Doppler Imager, Huairou (China), and Big Bear measurements of the B-z-component in the photosphere for nine active regions. We show that there is no universal behavior in the scaling of the B-z-structure functions for different active regions. Our previous study has shown that scaling for a given active region is caused by intermittency in the field, epsilon((B))(x), describing the magnetic energy dissipation. When intermittency is weak, the B-z field behaves as a passive scalar in the turbulent flow, and the energy dissipation is largely determined by the dissipation of kinetic energy in the active regions with low are productivity. However, when the field epsilon((B))(x) is highly intermittent, the structure functions behave as transverse structure functions of a fully developed turbulent vector field, and the scaling of the energy dissipation is mostly determined by the dissipation of the magnetic energy (active regions with strong flaring productivity). Based on this recent result, we find that the dissipation spectrum of the B-z-component is strongly related to the level of are productivity in a solar active region. When the are productivity is high, the corresponding spectrum is less steep. We also find that during the evolution of NOAA Active Region 9393, the B-z dissipation spectrum becomes less steep as the active region's are activity increases. Our results suggest that the reorganization of the magnetic field at small scales is also relevant to flaring: the relative fraction of small-scale fluctuations of magnetic energy dissipation increases as an active region becomes prone to producing strong flares. Since these small-scale changes seem to begin long before the start of a solar are, we suggest that the relation between scaling exponents, calculated by using only measurements of the B-z-component, and are productivity of an active region can be used to monitor and forecast are activity.
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