Dong Li Purple Mountain Observatory, CAS

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Dong Li lidong@pmo.ac.cn Purple Mountain Observatory, CAS Spectral and Imaging observations of quasi-periodic pulsations in solar flares Dong Li lidong@pmo.ac.cn Purple Mountain Observatory, CAS

Outlines 4-minute QPPs detected from spectra and images (Li et al., 2015, ApJ) 1-minute QPPs seen in a Solar Flare (Ning 2017, Solar physics) QPPs with changing periods depending on the thermal or nonthermal components in a flare (Li et al., 2017, A&A) QPPs in a circular-ribbon flare (Zhang et al., 2016, ApJ) QPPs with increasing periods with HXR energies

4-minute QPPs See detailed in Li et al., 2015 2015ApJ...807...72L

2014-9-10 X1.6

QPPs in HXR and radio channels Periods ~4 minutes Time delay: ~8 minutes

IRIS slit position Fixed flare ribbon front

QPPs in spectra Periods QPP peaks ~4 minutes broad line width red shift

QPPs in EUV/UV bands Periods ~4 minutes

Summary The 4-minute QPPs are found in a broad wavelength from HXR through EUV to the radio, indicating that the QPPs are produced by the non-thermal electrons that are accelerated by the quasi-periodic magnetic reconnections. Imaging observations of SDO/AIA show that the QPPs originate from the flare ribbon front. Spectral observations of IRIS present that the QPP peaks tend to a broad line width and a redshift velocity.

1-minute QPPs See detailed in Ning, 2017 2017SoPh..292...11N

QPPs in SXR band 2014-9-10 X1.6 1 – 8 Å

QPPs in EUV/UV and X-ray bands

QPPs in from GOES temperature and emission measure

1-minute QPPs positions AIA 335 Fpt1 Lt Fpt2

Summary 1-minute QPPs are simultaneously found in SXR, EUV/UV, HXR emissions, and it varies in a broad range of ≈30 – 120 s. The 1-minute QPPs tend to originate from the flare loop footpoints.

QPPs with changing periods See detailed in Li et al., 2017 2017A&A...597L...4L

2014-10-27 M7.1 flare

Flare position NOAA AR12192

QPPs in X-ray emissions HXR SXR

QPPs in Microwave emissions

QPPs from EVE observation Derivatives SXR

Summary The QPPs period changes from thermal (SXR) to nonthermal (HXR, microwave) components in a single flare that occur at almost the same time. The period ratio is exactly 2.0, which might be due to the modulations of the magnetic reconnection rate by the fundamental and harmonic modes of MHD waves.

QPPs in a circular-ribbon flare See detailed in Zhang et al., 2016 2016ApJ...832...65Z

circular-ribbon flare 2015-10-16 C3.1

Time derivative of SXR flux 1–8 Å P=32 s

Si IV intensity P=33-42 s

Summary During the impulsive phase of flare, the Si IV line intensities and SXR derivative show QPPs with periods of 32–42 s. The QPPs were most probably caused by intermittent null-point magnetic reconnections modulated by the fast wave.

QPPs with increasing periods

2014-9-10 X1.6

QPPs in lower energy P=25-35 s Mean: 30 s

QPPs in medium-energy P=30-60 s

QPPs in higher energy P=50-70 s Mean: 60 s

Summary The QPPs show increasing periods with energies at HXR channels. The QPPs show increasing periods with time from HXR emissions. The QPPs with double periods (~30 s and ~60 s) at HXR channels could be due to the modulations of the magnetic reconnection rate by the higher order harmonic modes of MHD wave.

Type II burst P=25-35 s Mean: 30 s ?

IRIS Fitting

THANK YOU!