A physics-based method that can predict imminent large solar flares

被引:80
作者
Kusano, Kanya [1 ]
Iju, Tomoya [2 ]
Bamba, Yumi [1 ,3 ]
Inoue, Satoshi [1 ]
机构
[1] Nagoya Univ, Inst Space Earth Environm Res, Nagoya, Aichi 4648601, Japan
[2] Natl Astron Observ Japan, Mitaka, Tokyo 1818588, Japan
[3] Nagoya Univ, Inst Adv Res, Nagoya, Aichi 4648601, Japan
来源
SCIENCE | 2020年 / 369卷 / 6503期
关键词
TRIGGER MECHANISM; KINK INSTABILITY; SPACE-WEATHER;
D O I
10.1126/science.aaz2511
中图分类号
O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];
学科分类号
07 ; 0710 ; 09 ;
摘要
Solar flares are highly energetic events in the Sun's corona that affect Earth's space weather. The mechanism that drives the onset of solar flares is unknown, hampering efforts to forecast them, which mostly rely on empirical methods. We present the k-scheme, a physics-based model to predict large solar flares through a critical condition of magnetohydrodynamic instability, triggered by magnetic reconnection. Analysis of the largest (X-class) flares from 2008 to 2019 (during solar cycle 24) shows that the k-scheme predicts most imminent large solar flares, with a small number of exceptions for confined flares. We conclude that magnetic twist flux density, close to a magnetic polarity inversion line on the solar surface, determines when and where solar flares may occur and how large they can be.
引用
收藏
页码:587 / 591
页数:5
相关论文
共 30 条
  • [1] A COMPARISON OF FLARE FORECASTING METHODS. I. RESULTS FROM THE "ALL-CLEAR" WORKSHOP
    Barnes, G.
    Leka, K. D.
    Schrijver, C. J.
    Colak, T.
    Qahwaji, R.
    Ashamari, O. W.
    Yuan, Y.
    Zhang, J.
    McAteer, R. T. J.
    Bloomfield, D. S.
    Higgins, P. A.
    Gallagher, P. T.
    Falconer, D. A.
    Georgoulis, M. K.
    Wheatland, M. S.
    Balch, C.
    Dunn, T.
    Wagner, E. L.
    [J]. ASTROPHYSICAL JOURNAL, 2016, 829 (02)
  • [2] The Helioseismic and Magnetic Imager (HMI) Vector Magnetic Field Pipeline: SHARPs - Space-Weather HMI Active Region Patches
    Bobra, M. G.
    Sun, X.
    Hoeksema, J. T.
    Turmon, M.
    Liu, Y.
    Hayashi, K.
    Barnes, G.
    Leka, K. D.
    [J]. SOLAR PHYSICS, 2014, 289 (09) : 3549 - 3578
  • [3] Sigmoidal morphology and eruptive solar activity
    Canfield, RC
    Hudson, HS
    Mckenzie, DE
    [J]. GEOPHYSICAL RESEARCH LETTERS, 1999, 26 (06) : 627 - 630
  • [4] An emerging flux trigger mechanism for coronal mass ejections
    Chen, PF
    Shibata, K
    [J]. ASTROPHYSICAL JOURNAL, 2000, 545 (01) : 524 - 531
  • [5] The Origin of Major Solar Activity: Collisional Shearing between Nonconjugated Polarities of Multiple Bipoles Emerging within Active Regions
    Chintzoglou, Georgios
    Zhang, Jie
    Cheung, Mark C. M.
    Kazachenko, Maria
    [J]. ASTROPHYSICAL JOURNAL, 2019, 871 (01)
  • [6] A Study of Pre-flare Solar Coronal Magnetic Fields: Magnetic Flux Ropes
    Duan, Aiying
    Jiang, Chaowei
    He, Wen
    Feng, Xueshang
    Zou, Peng
    Cui, Jun
    [J]. ASTROPHYSICAL JOURNAL, 2019, 884 (01)
  • [7] KINK INSTABILITY OF SOLAR CORONAL LOOPS AS THE CAUSE OF SOLAR-FLARES
    HOOD, AW
    PRIEST, ER
    [J]. SOLAR PHYSICS, 1979, 64 (02) : 303 - 321
  • [8] NONLINEAR FORCE-FREE EXTRAPOLATION OF THE CORONAL MAGNETIC FIELD BASED ON THE MAGNETOHYDRODYNAMIC RELAXATION METHOD
    Inoue, S.
    Magara, T.
    Pandey, V. S.
    Shiota, D.
    Kusano, K.
    Choe, G. S.
    Kim, K. S.
    [J]. ASTROPHYSICAL JOURNAL, 2014, 780 (01)
  • [9] Double Arc Instability in the Solar Corona
    Ishiguro, N.
    Kusano, K.
    [J]. ASTROPHYSICAL JOURNAL, 2017, 843 (02)
  • [10] Statistical Analysis of Torus and Kink Instabilities in Solar Eruptions
    Jing, Ju
    Liu, Chang
    Lee, Jeongwoo
    Ji, Hantao
    Liu, Nian
    Xu, Yan
    Wang, Haimin
    [J]. ASTROPHYSICAL JOURNAL, 2018, 864 (02)
123