Your search keyword '"Hou, Zhenyong"' showing total 145 results

1. Three types of solar coronal rain during magnetic reconnection between open and closed magnetic structures

Author

Qiao, Fangfang, Li, Leping, Tian, Hui, Hou, Zhenyong, Song, Hongqiang, Ji, Kaifan, and Sun, Zheng

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Coronal rain (CR) is a crucial part of the mass cycle between the corona and chromosphere. It includes the flare-driven CR and two types of quiescent CR separately along the non-flaring active region closed loops and along the open structures, labeled as types I, II, and III CR, respectively. Among them, types I and III CR are generally associated with magnetic reconnection. In this study, employing data taken by the Solar Dynamics Observatory (SDO) and the Solar Upper Transition Region Imager (SUTRI) on 2022 October 11, we report three types of CR during an interchange reconnection between open and closed magnetic filed structures above the southeastern solar limb. The open and closed structures converge, with the formation of current sheet at the interface, and reconnect. The newly-formed closed and open structures then recede from the reconnection region. During the reconnection, coronal condensation occurs along the reconnecting closed loops, and falls toward the solar surface along both loop legs as the type II CR. Subsequently, condensation happens in the newly-formed closed loops, and moves down toward the solar surface along both loop legs as the type I CR. Magnetic dips of the reconnecting open structures form during the reconnection. In the dips, condensation occurs, and propagates along the open structures toward the solar surface as the type III CR. Our results suggest that the reconnection rate may be crucial for the formation of types I and III CR during the reconnection., Comment: 17 pages, 8 figures

Published

2024

2. Localizing quasi-periodic pulsations in hard X-ray, microwave and Lya emissions of an X6.4 Flare

Author

Li, Dong, Hong, Zhenxiang, Hou, Zhenyong, and Su, Yang

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We report the simultaneous observations of quasi-periodic pulsations (QPPs) in wavelengths of hard X-ray (HXR), microwave, Ly{\alpha}, and ultraviolet (UV) emissions during the impulsive phase of an X6.4 flare on 2024 February 22 (SOL2024-02-22T22:08). The X6.4 flare shows three repetitive and successive pulsations in HXR and microwave wavebands, and they have an extremely-large modulation depth. The onset of flare QPPs is almost simultaneous with the start of magnetic cancellation between positive and negative fields. The wavelet power spectra suggest the presence of double periods, which are centered at about 200s and 95s, respectively. The long-period QPP can also be detected in Ly$\alpha$ and UV wavebands at the flare area, and it could be observed in the adjacent sunspot. Our observations indicate that the flare QPPs are most likely triggered by accelerated electrons that are associated with periodic magnetic reconnections. The long period at about 200s is probably modulated by the slow magnetoacoustic wave originating from the neighboring sunspot, while the short period at about 95s could be regarded as its second harmonic mode., Comment: Published in ApJ

Published

2024

3. The Solar Origin of an Intense Geomagnetic Storm on 2023 December 1st: Successive Slipping and Eruption of Multiple Magnetic Flux Ropes

Author

Sun, Zheng, Li, Ting, Hou, Yijun, Tian, Hui, Wu, Ziqi, Li, Ke, Zhang, Yining, Li, Zhentong, Bai, Xianyong, Feng, Li, Li, Chuan, Hou, Zhenyong, Song, Qiao, Wang, Jingsong, and Zhou, Guiping

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

The solar eruption that occurred on 2023 November 28 (SOL2023-11-28) triggered an intense geomagnetic storm on Earth on 2023 December 1. The associated Earth's auroras manifested at the most southern latitudes in the northern hemisphere observed in the past two decades. In order to explore the profound geoeffectiveness of this event, we conducted a comprehensive analysis of its solar origin to offer potential factors contributing to its impact. Magnetic flux ropes (MFRs) are twisted magnetic structures recognized as significant contributors to coronal mass ejections (CMEs), thereby impacting space weather greatly. In this event, we identified multiple MFRs in the solar active region and observed distinct slipping processes of the three MFRs: MFR1, MFR2, and MFR3. All three MFRs exhibit slipping motions at a speed of 40--137 km s$^{-1}$, extending beyond their original locations. Notably, the slipping of MFR2 extends to $\sim$30 Mm and initiate the eruption of MFR3. Ultimately, MFR1's eruption results in an M3.4-class flare and a CME, while MFR2 and MFR3 collectively produce an M9.8-class flare and another halo CME. This study shows the slipping process in a multi-MFR system, showing how one MFR's slipping can trigger the eruption of another MFR. We propose that the CME--CME interactions caused by multiple MFR eruptions may contribute to the significant geoeffectiveness.

Published

2024

4. Numerous Bidirectionally Propagating Plasma Blobs near the Reconnection Site of a Solar Eruption

Author

Hou, Zhenyong, Tian, Hui, Madjarska, Maria S., Chen, Hechao, Samanta, Tanmoy, Bai, Xianyong, Li, Zhentong, Su, Yang, Chen, Wei, and Deng, Yuanyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Current sheet is a common structure involved in solar eruptions. However, it is observed in minority of the events and the physical properties of its fine structures during a solar eruption are rarely investigated. Here, we report an on-disk observation that displays 108 compact, circular or elliptic bright structures, presumably plasma blobs, propagating bidirectionally along a flare current sheet during a period of $\sim$24 minutes. From extreme ultraviolet images, we have investigated the temporal variation of the blob number around the flare peak time. The current sheet connects the flare loops and the erupting filament. The width, duration, projected velocity, temperature, and density of these blobs are $\sim$1.7$\pm$0.5\,Mm, $\sim$79$\pm$57\,s, $\sim$191$\pm$81\,\kms, $\sim$10$^{6.4\pm0.1}$ K, and $\sim$10$^{10.1\pm0.3}$ cm$^{-3}$, respectively. The reconnection site rises with a velocity of $\leqslant$69\,\kms. The observational results suggest that plasmoid instability plays an important role in the energy release process of solar eruptions., Comment: Accepted by A&A, 9 pages, and 5 figures

Published

2024

5. Persistent Upflows and Downflows at Active Region boundaries Observed by SUTRI and AIA

Author

Wu, Yuchuan, Hou, Zhenyong, Li, Wenxian, Bai, Xianyong, Song, Yongliang, Yang, Xiao, Hu, Ziyao, Deng, Yuanyong, and Ji, Kaifan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Upflows and downflows at active region (AR) boundaries have been frequently observed with spectroscopic observations at extreme ultraviolet (EUV) passbands. In this paper, we report the coexistence of upflows and downflows at the AR boundaries with imaging observations from the Solar Upper Transition Region Imager (SUTRI) and the Atmospheric Imaging Assembly (AIA). With their observations from 2022 September 21 to 2022 September 30, we find 17 persistent opposite flows occurring along the AR coronal loops. The upflows are prominent in the AIA 193 \AA images with a velocity of 50-200 km/s, while the downflows are best seen in the SUTRI 465 \AA and AIA 131 \AA images with a slower velocity of tens of kilometers per second (characteristic temperatures (log T(K)) for 193 \AA, 465 \AA and 131 \AA are 6.2, 5.7, 5.6, respectively). We also analyze the center-to-limb variation of the velocities for both upflows and downflows. The simultaneous observations of downflows and upflows can be explained by the chromosphere-corona mass-cycling process, in which the localized chromospheric plasma is impulsively heated to coronal temperature forming a upflow and then these upflows experience radiative cooling producing a downflow with the previously heated plasma returning to the lower atmosphere. In particular, the persistent downflows seen by SUTRI provide strong evidence of the cooling process in the mass cycle. For upflows associated with open loops, part of the plasma is able to escape outward and into the heliosphere as solar wind.

Published

2024

6. Formation of Fan-spine Magnetic Topology through Flux Emergence and Subsequent Jet Production

Author

Duan, Yadan, Tian, Hui, Chen, Hechao, Shen, Yuandeng, Sun, Zheng, Hou, Zhenyong, and Li, Chuan

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Fan-spine magnetic structure, as a fundamental three-dimensional topology in magnetic reconnection theory, plays a crucial role in producing solar jets. However, how fan-spine configurations form in the solar atmosphere remains elusive. Using the Chinese H$\alpha$ Solar Explorer (CHASE) and the Solar Dynamics Observatory (SDO), we present a case study on the complete buildup of fan-spine topology driven by flux emergence and the subsequent jet production. Two fan-spine structures and the two associated null points are present. Variations in null-point heights and locations were tracked over time during flux emergence. The north fan-spine structure is found to be created through magnetic reconnection between the newly emerged flux and the background field. Gentle reconnection persistently occurs after formation of the north fan-spine structure, resulting in weak plasma outflows. Subsequently, as flux emergence and magnetic helicity injection continue, the formation and eruption of mini-filaments after reconnection at the quasi-separatrix layer between the two nulls trigger three homologous jets. The CHASE observations reveal that the circular flare ribbon, inner bright patch, and remote brightening all exhibit redshifted signatures during these jet ejections. This work unveils the key role of flux emergence in the formation of fan-spine topology, and highlights the importance of mini-filaments for subsequent jet production., Comment: 20 pages, 7 figures accepted by the ApJL

Published

2024

7. Simultaneous detection of flare-associated kink oscillations and extreme-ultraviolet waves

Author

Li, Dong, Hou, Zhenyong, Bai, Xianyong, Li, Chuan, Fang, Matthew, Zhao, Haisheng, Wang, Jincheng, and Ning, Zongjun

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Kink oscillations, which are frequently observed in coronal loops and prominences, are often accompanied by extreme-ultraviolet (EUV) waves. However, much more needs to be explored regarding the causal relationships between kink oscillations and EUV waves. In this article, we report the simultaneous detection of kink oscillations and EUV waves that are both associated with an X2.1 flare on 2023 March 03 (SOL2023-03-03T17:39). The kink oscillations, which are almost perpendicular to the axes of loop-like structures, are observed in three coronal loops and one prominence. One short loop shows in-phase oscillation within the same period of 5.2 minutes at three positions. This oscillation could be triggered by the pushing of an expanding loop and interpreted as the standing kink wave. Time lags are found between the kink oscillations of the short loop and two long loops, suggesting that the kink wave travels in different loops. The kink oscillations of one long loop and the prominence are possibly driven by the disturbance of the CME, and that of another long loop might be attributed to the interaction of the EUV wave. The onset time of the kink oscillation of the short loop is nearly same as the beginning of an EUV wave. This fact demonstrates that they are almost simultaneous. The EUV wave is most likely excited by the expanding loop structure and shows two components. The leading component is a fast coronal wave, and the trailing one could be due to the stretching magnetic field lines., Comment: accepted for publication in the Science China Technological Sciences

Published

2023

8. The triggering process of an X-class solar flare on a small quadrupolar active region

Author

Song, Qiao, Wang, Jing-Song, Zhang, Xiaoxin, Chen, Hechao, Yang, Shuhong, Hou, Zhenyong, Hou, Yijun, Ye, Qian, Zhang, Peng, Hu, Xiuqing, Dun, Jinping, Zong, Weiguo, Bai, Xianyong, Chen, Bo, He, Lingping, and Song, Kefei

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The occurrence of X-class solar flares and their potential impact on the space weather often receive great attention than other flares. But predicting when and where an X-class flare will occur is still a challenge. With the multi-wavelength observation from the Solar Dynamics Observatory and FengYun- 3E satellite, we investigate the triggering of a GOES X1.0 flare occurring in the NOAA active region (AR) 12887. Our results show that this unique X-class flare is bred in a relatively small but complex quadrupolar AR. Before the X-class flare, two filaments (F1 and F2) exist below a null-point topology of the quadrupolar AR. Magnetic field extrapolation and observation reveal that F1 and F2 correspond to two magnetic flux ropes with the same chirality and their adjacent feet rooted at nonconjugated opposite polarities, respectively. Interestingly, these two polarities collide rapidly, accompanied by photospheric magnetic flux emergence, cancellation and shear motion in the AR center. Above this site, F1 and F2 subsequently intersect and merge to a longer filament (F3) via a tether-cutting-like reconnection process. As a result, the F3 rises and erupts, involving the large-scale arcades overlying filament and the quadrupolar magnetic field above the AR, and eventually leads to the eruption of the X-class flare with a quasi-X-shaped flare ribbon and a coronal mass ejection. It suggests that the rapid collision of nonconjugated opposite polarities provides a key condition for the triggering of this X-class flare, and also provides a featured case for flare trigger mechanism and space weather forecasting., Comment: 24 pages, 7 figures, accepted for publication in ApJ

Published

2023

9. Internal activities in a solar filament and heating to its threads

Author

Wei, Hengyuan, Huang, Zhenghua, Li, Chuan, Hou, Zhenyong, Qiu, Ye, Fu, Hui, Bai, Xianyong, and Xia, Lidong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Filaments are one of the most common features in the solar atmosphere, and are of significance in solar, stellar and laboratory plasma physics. Using data from the Chinese H$\alpha$ Solar Explorer, the Solar Upper Transition Region Imager and the Solar Dynamics Observatory, we report on multiwavelength imaging and spectral observations of the activation of a small filament. The filament activation produces several localized dynamic brightenings, which are probably produced by internal reconnections of the braided magnetic fields in the filament. The filament expands during the activation and its threads reconnect with the ambient magnetic fields, which leads to the formation of hot arcades or loops overlying the filament. The thermal energy of each of these localized brightenings is estimated in the order of $10^{25}-10^{27} erg$ and the total energy is estimated to be $\sim1.77 \times 10^{28} erg$. Our observations demonstrate that the internal magnetic reconnections in the filament can lead to localized heating to the filament threads and prompt external reconnections with ambient corona structures, and thus could contribute to the energy and mass transferring into the corona.

Published

2023

10. Observation of two splitting processes in a partial filament eruption on the sun: the role of breakout reconnection

Author

Sun, Zheng, Li, Ting, Tian, Hui, Hou, Yinjun, Hou, Zhenyong, Chen, Hechao, Bai, Xianyong, and Deng, Yuanyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Partial filament eruptions have often been observed, however, the physical mechanisms that lead to filament splitting are not yet fully understood. In this study, we present a unique event of a partial filament eruption that undergoes two distinct splitting processes. The first process involves vertical splitting and is accompanied by brightenings inside the filament, which may result from internal magentic reconnection within the filament. Following the first splitting process, the filament is separated into an upper part and a lower part. Subsequently, the upper part undergoes a second splitting, which is accompanied by a coronal blowout jet. An extrapolation of the coronal magnetic field reveals a hyperbolic flux tube structure above the filament, indicating the occurrence of breakout reconnection that reduces the constraning field above. Consequently, the filament is lifted up, but at a nonuniform speed. The high-speed part reaches the breakout current sheet to generate the blowout jet, while the low-speed part falls back to the solar surface, resulting in the second splitting. In addition, continuous brightenings are observed along the flare ribbons, suggesting the occurrence of slipping reconnection process. This study presents, for the first time, the unambiguous observation of a two-stage filament splitting process, advancing our understanding of the complex dynamics of solar eruptions., Comment: 12 pages, 8 figures

Published

2023

11. A Type II Radio Burst Driven by a Blowout Jet on the Sun

Author

Hou, Zhenyong, Tian, Hui, Su, Wei, Madjarska, Maria S., Chen, Hechao, Zheng, Ruisheng, Bai, Xianyong, and Deng, Yuanyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Type II radio bursts are often associated with coronal shocks that are typically driven by coronal mass ejections (CMEs) from the Sun. Here, we conduct a case study of a type II radio burst that is associated with a C4.5 class flare and a blowout jet, but without the presence of a CME. The blowout jet is observed near the solar disk center in the extreme-ultraviolet (EUV) passbands with different characteristic temperatures. Its evolution involves an initial phase and an ejection phase with a velocity of 560 km/s. Ahead of the jet front, an EUV wave propagates at a projected velocity of 403 km/s in the initial stage. The moving velocity of the source region of the type II radio burst is estimated to be 641 km/s, which corresponds to the shock velocity against the coronal density gradient. The EUV wave and the type II radio burst are closely related to the ejection of the blowout jet, suggesting that both are likely the manifestation of a coronal shock driven by the ejection of the blowout jet. The type II radio burst likely starts lower than those associated with CMEs. The combination of the velocities of the radio burst and the EUV wave yields a modified shock velocity at 757 km/s. The Alfven Mach number is in the range of 1.09-1.18, implying that the shock velocity is 10%-20% larger than the local Alfven velocity., Comment: Accepted by ApJ, 17 pages, and 6 figures

Published

2023

12. Traveling kink oscillations of coronal loops launched by a solar flare

Author

Li, Dong, Bai, Xianyong, Tian, Hui, Su, Jiangtao, Hou, Zhenyong, Deng, Yuanyong, Ji, Kaifan, and Ning, Zongjun

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We investigate the traveling kink oscillation triggered by a solar flare on 2022 September 29. The observational data is mainly measured by the Solar Upper Transition Region Imager (SUTRI), the Atmospheric Imaging Assembly (AIA), and the Spectrometer/Telescope for Imaging X-rays (STIX). The transverse oscillations with apparent decaying in amplitudes, which are nearly perpendicular to the oscillating loop, are observed in passbands of SUTRI 465 A, AIA 171 A, and 193 A. The decaying oscillation is launched by a solar flare erupted closely to one footpoint of coronal loops, and then it propagates along several loops. Next, the traveling kink wave is evolved to a standing kink oscillation. To the best of our knowledge, this is the first report of the evolution of a traveling kink pulse to a standing kink wave along coronal loops. The standing kink oscillation along one coronal loop has a similar period of about 6.3 minutes at multiple wavelengths, and the decaying time is estimated to about 9.6-10.6 minutes. Finally, two dominant periods of 5.1 minutes and 2.0 minutes are detected in another oscillating loop, suggesting the coexistence of the fundamental and third harmonics., Comment: 8 pages, 8 figures, accepted by A&A

Published

2023

13. Simultaneous detection of flare-associated kink oscillations and extreme-ultraviolet waves

Author

Li, Dong, Hou, ZhenYong, Bai, XianYong, Li, Chuan, Fang, Matthew, Zhao, HaiSheng, Wang, JinCheng, and Ning, ZongJun

Published

2024

14. Why 'solar tsunamis' rarely leave their imprints in the chromosphere

Author

Zheng, Ruisheng, Liu, Yihan, Liu, Wenlong, Wang, Bing, Hou, Zhenyong, Feng, Shiwei, Kong, Xiangliang, Huang, Zhenghua, Song, Hongqiang, Tian, Hui, Chen, Pengfei, Erdélyi, Robertus, and Chen, Yao

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Solar coronal waves frequently appear as bright disturbances that propagate globally from the eruption center in the solar atmosphere, just like the tsunamis in the ocean on Earth. Theoretically, coronal waves can sweep over the underlying chromosphere and leave an imprint in the form of Moreton wave, due to the enhanced pressure beneath their coronal wavefront. Despite the frequent observations of coronal waves, their counterparts in the chromosphere are rarely detected. Why the chromosphere rarely bears the imprints of solar tsunamis remained a mystery since their discovery three decades ago. To resolve this question, all coronal waves and associated Moreton waves in the last decade have been initially surveyed, though the detection of Moreton waves could be hampered by utilising the low-quality H$\alpha$ data from Global Oscillations Network Group. Here, we present 8 cases (including 5 in Appendix) of the coexistence of coronal and Moreton waves in inclined eruptions where it is argued that the extreme inclination is key to providing an answer to address the question. For all these events, the lowest part of the coronal wavefront near the solar surface appears very bright, and the simultaneous disturbances in the solar transition region and the chromosphere predominantly occur beneath the bright segment. Therefore, evidenced by observations, we propose a scenario for the excitation mechanism of the coronal-Moreton waves in highly inclined eruptions, in which the lowest part of a coronal wave can effectively disturb the chromosphere even for a weak (e.g., B-class) solar flare., Comment: 24 pages, 14 figures

Published

2023

15. Heating of quiescent coronal loops caused by nearby eruptions observed with the Solar Dynamics Observatory and the Solar Upper Transition Region Imager

Author

Li, Leping, Tian, Hui, Chen, Huadong, Song, Hongqiang, Hou, Zhenyong, Bai, Xianyong, Ji, Kaifan, and Deng, Yuanyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

How structures, e.g., magnetic loops, in the upper atmosphere, i.e., the transition region and corona, are heated and sustained is one of the major unresolved issues in solar and stellar physics. Various theoretical and observational studies on the heating of coronal loops have been undertaken. The heating of quiescent loops caused by eruptions is, however, rarely observed. In this study, employing data from the Solar Dynamics Observatory (SDO) and Solar Upper Transition Region Imager (SUTRI), we report the heating of quiescent loops associated with nearby eruptions. In active regions (ARs) 13092 and 13093, a long filament and a short filament, and their overlying loops are observed on 2022 September 4. In AR 13093, a warm channel erupted toward the northeast, whose material moved along its axis toward the northwest under the long filament, turned to the west above the long filament, and divided into two branches falling to the solar surface. Subsequently, the short filament erupted toward the southeast. Associated with these two eruptions, the quiescent loops overlying the long filament appeared in SDO/Atmospheric Imaging Assembly (AIA) high-temperature images, indicating the heating of loops. During the heating, signature of magnetic reconnection between loops is identified, including the inflowing motions of loops, and the formation of X-type structures and newly reconnected loops. The heated loops then cooled down. They appeared sequentially in AIA and SUTRI lower-temperature images. All the results suggest that the quiescent loops are heated by reconnection between loops caused by the nearby warm channel and filament eruptions., Comment: 20 pages, 12 figures, accepted for publication in ApJ

Published

2023

16. The Solar Upper Transition Region Imager (SUTRI) onboard the SATech-01 satellite

Author

Bai, Xianyong, Tian, Hui, Deng, Yuanyong, Wang, Zhanshan, Yang, Jianfeng, Zhang, Xiaofeng, Zhang, Yonghe, Qi, Runze, Wang, Nange, Gao, Yang, Yu, Jun, He, Chunling, Shen, Zhengxiang, Shen, Lun, Guo, Song, Hou, Zhenyong, Ji, Kaifan, Bi, Xingzi, Duan, Wei, Yang, Xiao, Lin, Jiaben, Hu, Ziyao, Song, Qian, Yang, Zihao, Chen, Yajie, Qiao, Weidong, Ge, Wei, Li, Fu, Jin, Lei, He, Jiawei, Chen, Xiaobo, Zhu, Xiaocheng, He, Junwang, Shi, Qi, Liu, Liu, Li, Jinsong, Xu, Dongxiao, Liu, Rui, Li, Taijie, Feng, Zhenggong, Wang, Yamin, Fan, Chengcheng, Liu, Shuo, Guo, Sifan, Sun, Zheng, Wu, Yuchuan, Li, Haiyu, Yang, Qi, Ye, Yuyang, Gu, Weichen, Wu, Jiali, Zhang, Zhe, Yu, Yue, Ye, Zeyi, Sheng, Pengfeng, Wang, Yifan, Li, Wenbin, Huang, Qiushi, and Zhang, Zhong

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Solar Upper Transition Region Imager (SUTRI) onboard the Space Advanced Technology demonstration satellite (SATech-01), which was launched to a sun-synchronous orbit at a height of 500 km in July 2022, aims to test the on-orbit performance of our newly developed Sc-Si multi-layer reflecting mirror and the 2kx2k EUV CMOS imaging camera and to take full-disk solar images at the Ne VII 46.5 nm spectral line with a filter width of 3 nm. SUTRI employs a Ritchey-Chretien optical system with an aperture of 18 cm. The on-orbit observations show that SUTRI images have a field of view of 41.6'x41.6' and a moderate spatial resolution of 8" without an image stabilization system. The normal cadence of SUTRI images is 30 s and the solar observation time is about 16 hours each day because the earth eclipse time accounts for about 1/3 of SATech-01's orbit period. Approximately 15 GB data is acquired each day and made available online after processing. SUTRI images are valuable as the Ne VII 46.5 nm line is formed at a temperature regime of 0.5 MK in the solar atmosphere, which has rarely been sampled by existing solar imagers. SUTRI observations will establish connections between structures in the lower solar atmosphere and corona, and advance our understanding of various types of solar activity such as flares, filament eruptions, coronal jets and coronal mass ejections., Comment: 29pages,16figures

Published

2023

17. The Solar Origin of an Intense Geomagnetic Storm on 1 December 2023: Successive Slipping and Eruption of Multiple Magnetic Flux Ropes

Author

Sun, Zheng, Li, Ting, Hou, Yijun, Tian, Hui, Wu, Ziqi, Li, Ke, Zhang, Yining, Li, Zhentong, Bai, Xianyong, Feng, Li, Li, Chuan, Hou, Zhenyong, Song, Qiao, Wang, Jingsong, and Zhou, Guiping

Published

2024

18. Cross-loop propagation of a quasi-periodic extreme-ultraviolet wave train triggered by successive stretching of magnetic field structures during a solar eruption

Author

Sun, Zheng, Tian, Hui, Chen, P. F., Yao, Shuo, Hou, Zhenyong, Chen, Hechao, and Chen, Linjie

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Solar extreme-ultraviolet (EUV) waves generally refer to large-scale disturbances propagating outward from sites of solar eruptions in EUV imaging observations. Using the recent observations from the Atmospheric Imaging Assembly (AIA) on board the Solar Dynamics Observatory (SDO), we report a quasi-periodic wave train propagating outward at an average speed of $\sim$308 km s$^{-1}$. At least five wavefronts can be clearly identified with the period being $\sim$120 s. These wavefronts originate from the coronal loop expansion, which propagates with an apparent speed of $\sim$95 km s$^{-1}$, about 3 times slower than the wave train. In the absence of a strong lateral expansion, these observational results might be explained by the theoretical model of Chen et al. (2002), which predicted that EUV waves may have two components: a faster component that is a fast-mode magnetoacoustic wave or shock wave and a slower apparent front formed as a result of successive stretching of closed magnetic field lines. In this scenario, the wave train and the successive loop expansion we observed likely correspond to the fast and slow components in the model, respectively., Comment: 9 pages, 4 figures

Published

2022

19. A new post-hoc flat field measurement method for the Solar X-ray and Extreme Ultraviolet Imager onboard the Fengyun-3E satellite

Author

Song, Qiao, Bai, Xianyong, Chen, Bo, Hu, Xiuqing, Chen, Yajie, Hou, Zhenyong, Zhang, Xiaofan, He, Lingping, Song, Kefei, Zhang, Peng, Wang, Jing-Song, Zhang, Xiaoxin, Zong, Weiguo, Dun, Jinping, Tian, Hui, and Deng, Yuanyong

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The extreme ultraviolet (EUV) observations are widely used in solar activity research and space weather forecasting since they can observe both the solar eruptions and the source regions of the solar wind. Flat field processing is indispensable to remove the instrumental non-uniformity of a solar EUV imager in producing high-quality scientific data from original observed data. Fengyun-3E (FY-3E) is a meteorological satellite operated in Sun-synchronous orbit, and the routine EUV imaging data from the Solar X-ray and Extreme Ultraviolet Imager (X-EUVI) onboard FY-3E has the characteristics of concentric rotation. Taking advantage of the concentric rotation, we propose a post-hoc flat field measurement method for its EUV 195 channel in this paper. This method removes small-scale and time-varying component of the coronal activities by taking the median value for each pixel along the time axis of a concentric rotation data cube, and then derives large-scale and invariable component of the quiet coronal radiation, and finally generates a flat field image. Analysis shows that our method is able to measure the instrumental spot-like non-uniformity possibly caused by contamination on the detector, which mostly disappears after the in-orbit self-cleaning process. It can also measure the quasi-periodic grid-like non-uniformity, possibly from the obscuration of the support mesh on the rear filter. After flat field correction, these instrumental non-uniformities from the original data are effectively removed. X-EUVI 195 data after dark and flat field corrections are consistent with the 193 channel data from SDO/AIA, verifying the suitability of the method. Our method is not only suitable for FY-3E/X-EUVI but also a candidate method for the flat field measurement of future solar EUV telescopes., Comment: 14 pages, 6 figures, Accepted for publication in RAA (Research in Astronomy and Astrophysics)

Published

2022

20. Detection of Flare-induced Plasma Flows in the Corona of EV Lac with X-ray Spectroscopy

Author

Chen, Hechao, Tian, Hui, Li, Hao, Wang, Jianguo, Lu, Hongpeng, Xu, Yu, Hou, Zhenyong, and Wu, Yuchuan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Stellar flares are characterized by sudden enhancement of electromagnetic radiation from the atmospheres of stars. Compared to their solar counterparts, our knowledge on the coronal plasma dynamics of stellar flares and their connection to coronal mass ejections (CMEs) remains very limited. With time-resolved high-resolution spectroscopic observations from the \textit{Chandra} X-ray observatory, we detected noticeable coronal plasma flows during several stellar flares on a nearby dMe star EV Lac. In the observed spectra of O~{\sc{viii}} (3 MK), Fe~{\sc{xvii}} (6 MK), Mg~{\sc{xii}} (10 MK), and Si~{\sc{xiv}} (16 MK) lines, these flare-induced upflows/downflows appear as significant Doppler shifts of several tens to \speed{130}, and the upflow velocity generally increases with temperature. Variable line ratios of the Si~{\sc{xiii}} triplet reveal that these plasma flows in most flares are accompanied by an increase of the coronal plasma density and temperature. We interpret these results as X-ray evidences for chromospheric evaporation on EV Lac. In two successive flares, the plasma flow pattern and a sharp increase of the measured coronal density are highly suggestive of explosive evaporation. The transition from redshifts to blueshifts in such an explosive evaporation occurs at a temperature of at least 10 MK, much higher than that observed in solar flares ($\sim$1 MK). However, in one flare the cool and warm upflows appear to be accompanied by a decreasing plasma density, which might be explained by a stellar filament/prominence eruption coupled to this flare. These results provide important clues to understand the coronal plasma dynamics during flares on M dwarfs., Comment: accepted by ApJ

Published

2022

21. Sun-as-a-star spectroscopic observations of the line-of-sight velocity of a solar eruption on October 28, 2021

Author

Xu, Yu, Tian, Hui, Hou, Zhenyong, Yang, Zihao, Gao, Yuhang, and Bai, Xianyong

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

The propagation direction and true velocity of a solar coronal mass ejection, which are among the most decisive factors for its geo-effectiveness, are difficult to determine through single-perspective imaging observations. Here we show that Sun-as-a-star spectroscopic observations, together with imaging observations, could allow us to solve this problem. Using observations of the Extreme-ultraviolet Variability Experiment onboard the Solar Dynamics Observatory, we found clear blue-shifted secondary emission components in extreme ultraviolet spectral lines during a solar eruption on October 28, 2021. From simultaneous imaging observations, we found that the secondary components are caused by a mass ejection from the flare site. We estimated the line-of-sight (LOS) velocity of the ejecta from both the double Gaussian fitting method and the red-blue asymmetry analysis. The results of both methods agree well with each other, giving an average LOS velocity of the plasma of $\sim 423~\rm{km~s^{-1}}$. From the $304$ \AA~image series taken by the Extreme Ultraviolet Imager onboard the Solar Terrestrial Relation Observatory-A (STEREO-A) spacecraft, we estimated the plane-of-sky (POS) velocity from the STEREO-A viewpoint {to be around $587~\rm{km~s^{-1}}$}. The full velocity of the bulk motion of the ejecta was then computed by combining the imaging and spectroscopic observations, which turns out to be around $596~\rm{km~s^{-1}}$ with an angle of $42.4^\circ$ to the west of the Sun-Earth line and $16.0^\circ$ south to the ecliptic plane., Comment: accepted by ApJ

Published

2022

22. Three-dimensional Propagation of the Global EUV Wave associated with a solar eruption on 2021 October 28

Author

Hou, Zhenyong, Tian, Hui, Wang, Jing-Song, Zhang, Xiaoxin, Song, Qiao, Zheng, Ruisheng, Chen, Hechao, Chen, Bo, Bai, Xianyong, Chen, Yajie, He, Lingping, Song, Kefei, Zhang, Peng, Hu, Xiuqing, Dun, Jinping, Zong, Weiguo, Song, Yongliang, Xu, Yu, and Tan, Guangyu

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We present a case study for the global extreme ultraviolet (EUV) wave and its chromospheric counterpart `Moreton-Ramsey wave' associated with the second X-class flare in Solar Cycle 25 and a halo coronal mass ejection (CME). The EUV wave was observed in the H$\alpha$ and EUV passbands with different characteristic temperatures. In the 171 {\AA} and 193/195 {\AA} images, the wave propagates circularly with an initial velocity of 600-720 km s$^{-1}$ and a deceleration of 110-320 m s$^{-2}$. The local coronal plasma is heated from log(T/K)=5.9 to log(T/K)=6.2 during the passage of the wavefront. The H$\alpha$ and 304 {\AA} images also reveal signatures of wave propagation with a velocity of 310-540 km s$^{-1}$. With multi-wavelength and dual-perspective observations, we found that the wavefront likely propagates forwardly inclined to the solar surface with a tilt angle of ~53.2$^{\circ}$. Our results suggest that this EUV wave is a fast-mode magnetohydrodynamic wave or shock driven by the expansion of the associated CME, whose wavefront is likely a dome-shaped structure that could impact the upper chromosphere, transition region and corona., Comment: Accepted by ApJ, 15 pages, and 7 figures

Published

2022

23. Coronal Condensation as the Source of Transition Region Supersonic Downflows above a Sunspot

Author

Chen, Hechao, Tian, Hui, Li, Leping, Peter, Hardi, Chitta, Lakshmi Pradeep, and Hou, Zhenyong

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics

Abstract

Plasma loops or plumes rooted in sunspot umbrae often harbor downflows with speeds of 100 km/s. These downflows are supersonic at transition region temperatures of 0.1 MK. The source of these flows is not well understood. We aim to investigate the source of sunspot supersonic downflows (SSDs) in AR 12740 using simultaneous spectroscopic and imaging observations. We identified SSD events from multiple raster scans of a sunspot by the Interface Region Imaging Spectrograph, and calculated the electron densities, mass fluxes and velocities of these SSDs. The EUV images provided by the AIA onboard the SDO and the EUVI onboard the STEREO were employed to investigate the origin of these SSDs and their associated coronal rain. Almost all the identified SSDs appear at the footpoints of sunspot plumes and are temporally associated with appearance of chromospheric bright dots inside the sunspot umbra. Dual-perspective EUV imaging observations reveal a large-scale closed magnetic loop system spanning the sunspot region and a remote region. We observed that the SSDs are caused by repeated coronal rain that forms and flows along these closed magnetic loops toward the sunspot. One episode of coronal rain clearly indicates that reconnection near a coronal X-shaped structure first leads to the formation of a magnetic dip. Subsequently, hot coronal plasma catastrophically cools from 2 MK in the dip region via thermal instability. This results in the formation of a transient prominence in the dip, from which the cool gas mostly slides into the sunspot along inclined magnetic fields under the gravity. This drainage process manifests as a continuous rain flow, which lasts for around 2 hrs and concurrently results in a nearly steady SSD event. Our results demonstrate that coronal condensation in magnetic dips can result in the quasi-steady sunspot supersonic downflows.

Published

2021

24. Statistical properties of H{\alpha} jets in the polar coronal hole and their implications in coronal activities

Author

Qi, Youqian, Huang, Zhenghua, Xia, Lidong, Fu, Hui, Guo, Mingzhe, Hou, Zhenyong, Liu, Weixin, Sun, Mingzhe, and Liu, Dayang

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Dynamic features, such as chromospheric jets, transition region network jets, coronal plumes and coronal jets, are abundant in the network regions of the solar polar coronal holes. We investigate the relationship between chromospheric jets and coronal activities (e.g., coronal plumes and jets).We analyze observations of a polar coronal hole including the filtergrams that were taken by the New Vacuum Solar Telescope (NVST) at the H{\alpha}-0.6 {\AA}to study the H{\alpha} jets,and the Atmospheric Imaging Assembly (AIA) 171 {\AA} images to follow the evolution of coronal activities. H{\alpha} jets are persistent in the network regions, only some regions (denoted as R1-R5) are rooted with discernible coronal plumes.With an automated method, we identify and track 1 320 H{\alpha} jets in the network regions. We find that the average lifetime, height and ascending speed of the H{\alpha} jets are 75.38 s, 2.67 Mm, 65.60 km s$^{-1}$, respectively. The H{\alpha} jets rooted in R1-R5 are higher and faster than those in the others. We also find that propagating disturbances (PDs) in coronal plumes have a close connection with the H{\alpha} jets. The speeds of 28 out of 29 H{\alpha} jets associated with PDs are about 50 km s$^{-1}$ . In a case of coronal jet, we find that the speeds of both the coronal jet and the H{\alpha} jet are over 150 km s$^{-1}$, suggesting that both cool and hot jets can be coupled together. Based on our analyses, it is evident that more dynamic H{\alpha} jets could release the energies to the corona, which might be the results of the development of Kelvin-Helmholtz instability (KHi) or small-scaled magnetic activities. We suggest that chromospheric jets, transition region network jets and ray-like features in the corona are coherent phenomena, and they are important tunnels for cycling energy and mass in the solar atmosphere., Comment: 13 pages,6 figures,accepted for publication in A&A

Published

2021

25. Coronal microjets in quiet-Sun regions observed with the Extreme Ultraviolet Imager onboard Solar Orbiter

Author

Hou, Zhenyong, Tian, Hui, Berghmans, David, Chen, Hechao, Teriaca, Luca, Schuhle, Udo, Gao, Yuhang, Chen, Yajie, He, Jiansen, Wang, Linghua, and Bai, Xianyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We report the smallest coronal jets ever observed in the quiet Sun with recent high resolution observations from the High Resolution Telescopes (HRI-EUV and HRI-Ly{\alpha}) of the Extreme Ultraviolet Imager (EUI) onboard Solar Orbiter. In the HRI-EUV (174 {\AA}) images, these microjets usually appear as nearly collimated structures with brightenings at their footpoints. Their average lifetime, projected speed, width, and maximum length are 4.6 min, 62 km s^(-1), 1.0 Mm, and 7.7 Mm, respectively. Inverted-Y shaped structures and moving blobs can be identified in some events. A subset of these events also reveal signatures in the HRI-Ly{\alpha} (H I Ly{\alpha} at 1216 {\AA}) images and the extreme ultraviolet images taken by the Atmospheric Imaging Assembly onboard the Solar Dynamics Observatory. Our differential emission measure analysis suggests a multi-thermal nature and an average density of ~1.4x10^9 cm^(-3) for these microjets. Their thermal and kinetic energies were estimated to be ~3.9x10^24 erg and ~2.9x10^23 erg, respectively, which are of the same order of the released energy predicted by the nanoflare theory. Most events appear to be located at the edges of network lanes and magnetic flux concentrations, suggesting that these coronal microjets are likely generated by magnetic reconnection between small-scale magnetic loops and the adjacent network field., Comment: Accepted by ApJL, 19 pages, 6 figures, and 2 tables

Published

2021

26. Dynamics in the transition region beneath active region upflows viewed by IRIS

Author

Huang, Zhenghua, Xia, Lidong, Fu, Hui, Hou, Zhenyong, and Wang, Ziyuan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Coronal upflows at the edges of active regions (AR), which are a possible source of slow solar wind, have been found to connect with dynamics in the transition region. To infer at what scale transition region dynamics connect to AR upflows, we investigate the statistical properties of the small-scale dynamics in the transition region underneath the upflows at the edge of AR NOAA 11934. With observations from the Interface Region Imaging Spectragraph (IRIS), we found that the Si IV 1403\,\AA\ Doppler map consists of numerous blue-shifted and red-shifted patches mostly with sizes less than 1\,$Mm^2$. The blue-shifted structures in the transition region tend to be brighter than the red-shifted ones, but their nonthermal velocities have no significant difference. With the SWAMIS feature tracking procedure, in IRIS slit-jaw 1400\,\AA\ images we found that dynamic bright dots with an average size of about 0.3\,$Mm^2$ and lifetimes mostly less than 200\,s spread all over the region. Most of the bright dots appear to be localised, without clear signature of propagation of plasma to a long distance on the projection plane. Surge-like motions with speeds about 15 km/s could be seen in some events at the boundaries of the upflow region, where the magnetic field appear to be inclined. We conclude that the transition region dynamics connecting to coronal upflows should occur in very fine scale, suggesting that the corresponding coronal upflows should also be highly-structured. It is also plausible that the transition region dynamics might just act as stimulation at the coronal base that then drives the upflows in the corona., Comment: 16 pages, 7 figures, accepted for publication in ApJ

Published

2021

27. Formation of solar quiescent coronal loops through magnetic reconnection in an emerging active region

Author

Hou, Zhenyong, Tian, Hui, Chen, Hechao, Zhu, Xiaoshuai, Huang, Zhenghua, Bai, Xianyong, He, Jiansen, Song, Yongliang, and Xia, Lidong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Coronal loops are building blocks of solar active regions. However, their formation mechanism is still not well understood. Here we present direct observational evidence for the formation of coronal loops through magnetic reconnection as new magnetic fluxes emerge into the solar atmosphere. Extreme-ultraviolet observations of the Atmospheric Imaging Assembly (AIA) onboard the Solar Dynamics Observatory (SDO) clearly show the newly formed loops following magnetic reconnection within a plasma sheet. Formation of the loops is also seen in the h{\alpha} line-core images taken by the New Vacuum Solar Telescope. Observations from the Helioseismic and Magnetic Imager onboard SDO show that a positive-polarity flux concentration moves towards a negative-polarity one with a speed of ~0.4 km/s, before the formation of coronal loops. During the loop formation process, we found signatures of flux cancellation and subsequent enhancement of the transverse field between the two polarities. The three-dimensional magnetic field structure reconstructed through a magnetohydrostatic model shows field lines consistent with the loops in AIA images. Numerous bright blobs with an average width of 1.37 Mm appear intermittently in the plasma sheet and move upward with a projected velocity of ~114 km/s. The temperature, emission measure and density of these blobs are about 3 MK, 2.0x10^(28) cm^(-5) and 1.2x10^(10) cm^(-3), respectively. A power spectral analysis of these blobs indicates that the observed reconnection is likely not dominated by a turbulent process. We have also identified flows with a velocity of 20 to 50 km/s towards the footpoints of the newly formed coronal loops., Comment: 15 pages, 7 figures, accepted for publication in ApJ

Published

2021

28. The chromospheric component of coronal bright points. Coronal and chromospheric responses to magnetic-flux emergence

Author

Madjarska, Maria S., Chae, Jongchul, Moreno-Insertis, Fernando, Hou, Zhenyong, Nobrega-Siverio, Daniel, Kwak, Hannah, Galsgaard, Klaus, and Cho, Kyuhyoun

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We investigate the chromospheric counterpart of small-scale coronal loops constituting a coronal bright point (CBP) and its response to a photospheric magnetic-flux increase accompanied by co-temporal CBP heating. We used co-observations from the AIA and HMI/SDO, together with data from the Fast Imaging Solar Spectrograph taken in the Halpha and Ca II 8542 lines. We used a new multi-layer spectral inversion technique to derive the temporal variations of the temperature of the Halpha loops (HLs). We find that the counterpart of the CBP, as seen at chromospheric temperatures, is composed of a bundle of dark elongated features named in this work Halpha loops, which constitute an integral part of the CBP loop magnetic structure. An increase in the photospheric magnetic flux due to flux emergence is accompanied by a rise of the coronal emission of the CBP loops, that is a heating episode. We also observe enhanced chromospheric activity associated with the occurrence of new HLs and mottles. While the coronal emission and magnetic flux increases appear to be co-temporal, the response of the Halpha counterpart of the CBP occurs with a small delay of less than 3 min. A sharp temperature increase is found in one of the HLs and in one of the CBP footpoints estimated at 46% and 55% with respect to the pre-event values, also starting with a delay of less than 3~min following the coronal heating episode. The low-lying CBP loop structure remains non-potential for the entire observing period. The magnetic topological analysis of the overlying corona reveals the presence of a coronal null point at the beginning and towards the end of the heating episode. The delay in the response of the chromospheric counterpart of the CBP suggests that the heating may have occurred at coronal heights., Comment: 14 pages, 14 figures, accepted for publication in A&A

Published

2020

29. How eruptions of a small filament feed materials to a nearby larger-scaled filament

Author

Wei, Hengyuan, Huang, Zhenghua, Hou, Zhenyong, Qi, Youqian, Fu, Hui, Li, Bo, and Xia, Lidong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

As one of the most common features in the solar atmosphere, filaments are significant not only in the solar physics but also in the stellar and laboratory plasma physics. With the New Vacuum Solar Telescope and the Solar Dynamics Observatory, here we report on multi-wavelength observations of eruptions of a small (30\arcsec) filament (SF) and its consequences while interacting with the ambient magnetic features including a large (300\arcsec) filament (LF). The eruptions of the SF drive a two-side-loop jet that is a result of magnetic reconnection between the SF threads and an over-lying magnetic channel. As a consequence of the eruption, the heating in the footpoints of the SF destabilises the barbs of the LF rooted nearby. Supersonic chromospheric plasma flows along the barbs of the LF are then observed in the \halpha\ passband and they apparently feed materials to the LF. We suggest they are shock-driven plasma flows or chromospheric evaporations, which both can be the consequences of the heating in the chromosphere by nonthermal particles generated in the magnetic reconnection associated with the two-side-loop jet. Our observations demonstrate that the destabilisation in the vicinity of the footpoints of a barb can drive chromospheric plasma feeding to the filament., Comment: 4 figures, 6 pages, accepted for publication in MNRAS:Letter

Published

2020

30. Transition region loops in the very late phase of flux-emergence in IRIS sit-and-stare observations

Author

Huang, Zhenghua, Li, Bo, Xia, Lidong, Shi, Mijie, Fu, Hui, and Hou, Zhenyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Loops are one of the fundamental structures that trace the geometry of the magnetic field in the solar atmosphere. Their evolution and dynamics provide a crucial proxy for studying how the magnetized structures are formed and heated in the solar atmosphere. Here, we report on spectroscopic observations of a set of transition region loops taken by the Interface Region Imaging Spectrograph (IRIS) at Si IV 1394 \AA\ with a sit-and-stare mode. The loops are corresponding to the flux emergence at its very late phase when the emerged magentic features in the photosphere have fully developed. We find the transition region loops are still expanding and moving upward with a velocity of a few kilometers per second ($\lesssim$10 km/s) at this stage. The expansion of the loops leads to interactions between themselves and the ambient field, which can drive magnetic reconnection evidenced by multiple intense brightenings, including transition region explosive events and IRIS bombs in the footpoint region associated with the moving polarity. A set of quasi-periodic brightenings with a period of about 130 s is found at the loop apex, from which the Si IV 1394 \AA\ profiles are significantly non-Gaussian with enhancements at both blue and red wings at Doppler velocities of about 50 km/s. We suggest that the transition region loops in the very late phase of flux emergence can be powered by heating events generated by the interactions between the expanding loops and the ambient fields and also by (quasi-)periodic processes, such as oscillation-modulated braiding reconnection., Comment: 10 pages, 5 figs, accepted for publication in ApJ

Published

2019

31. On the relation between transition region network jets and coronal plumes

Author

Qi, Youqian, Huang, Zhenghua, Xia, Lidong, Li, Bo, Fu, Hui, Liu, Weixin, Sun, Mingzhe, and Hou, Zhenyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Both coronal plumes and network jets are rooted in network lanes. The relationship between the two, however, has yet to be addressed. For this purpose, we perform an observational analysis using images acquired with the Atmospheric Imaging Assembly (AIA) 171{\AA} passband to follow the evolution of coronal plumes, the observations taken by the Interface Region Imaging Spectrograph (IRIS) slit-jaw 1330{\AA} to study the network jets, and the line-of-sight magnetograms taken by the Helioseismic and Magnetic Imager (HMI) to overview the the photospheric magnetic features in the regions. Four regions in the network lanes are identified, and labeled ``R1--R4''. We find that coronal plumes are clearly seen only in ``R1''&''R2'' but not in ``R3''&``R4'', even though network jets abound in all these regions. Furthermore, while magnetic features in all these regions are dominated by positive polarity, they are more compact (suggesting stronger convergence) in ``R1''&``R2'' than that in ``R3''&``R4''. We develop an automated method to identify and track the network jets in the regions. We find that the network jets rooted in ``R1''&``R2'' are higher and faster than that in ``R3''&``R4'',indicating that network regions producing stronger coronal plumes also tend to produce more dynamic network jets. We suggest that the stronger convergence in ``R1''&``R2'' might provide a condition for faster shocks and/or more small-scale magnetic reconnection events that power more dynamic network jets and coronal plumes., Comment: The preprint of an article accepted for publication in Solar Physics

Published

2019

32. Transition region bright dots in active regions observed by the Interface Region Imaging Spectrograph

Author

Hou, Zhenyong, Huang, Zhenghua, Xia, Lidong, Li, Bo, Madjarska, Maria S., and Fu, Hui

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The Interface Region Imaging Spectrograph (IRIS) reveals numerous small-scale (sub-arcsecond) brightenings that appear as bright dots sparkling the solar transition region in active regions. Here, we report a statistical study on these transition region bright dots. We use an automatic approach to identify 2742 dots in a Si IV raster image. We find that the average spatial size of the dots is 0.8 arcsec$^2$ and most of them are located in the faculae area. Their Doppler velocities obtained from the Si IV 1394 {\AA} line range from -20 to 20 km/s. Among these 2742 dots, 1224 are predominantly blue-shifted and 1518 are red-shifted. Their nonthermal velocities range from 4 to 50 km/s with an average of 24 km/s. We speculate that the bright dots studied here are small-scale impulsive energetic events that can heat the active region corona., Comment: 4 pages, 4 figures, publication in AIP Conference Proceedings

Published

2018

33. Observations of upward propagating waves in the transition region and corona above Sunspots

Author

Hou, Zhenyong, Huang, Zhenghua, Xia, Lidong, Li, Bo, and Fu, Hui

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We present observations of persistent oscillations of some bright features in the upper-chromosphere/transition-region above sunspots taken by IRIS SJ 1400 {\AA} and upward propagating quasi-periodic disturbances along coronal loops rooted in the same region taken by AIA 171 {\AA} passband. The oscillations of the features are cyclic oscillatory motions without any obvious damping. The amplitudes of the spatial displacements of the oscillations are about 1 $^{"}$. The apparent velocities of the oscillations are comparable to the sound speed in the chromosphere, but the upward motions are slightly larger than that of the downward. The intensity variations can take 24-53% of the background, suggesting nonlinearity of the oscillations. The FFT power spectra of the oscillations show dominant peak at a period of about 3 minutes, in consistent with the omnipresent 3 minute oscillations in sunspots. The amplitudes of the intensity variations of the upward propagating coronal disturbances are 10-15% of the background. The coronal disturbances have a period of about 3 minutes, and propagate upward along the coronal loops with apparent velocities in a range of 30-80 km/s. We propose a scenario that the observed transition region oscillations are powered continuously by upward propagating shocks, and the upward propagating coronal disturbances can be the recurrent plasma flows driven by shocks or responses of degenerated shocks that become slow magnetic-acoustic waves after heating the plasma in the coronal loops at their transition-region bases., Comment: 13 pages, 9 figures, accepted for publication in ApJ

Published

2018

34. Multiwavelength Observations for a Double-decker Filament Channel in AR 13102.

Author

Zhang, Yin, Tan, Baolin, Wang, Quan, Huang, Jing, Xu, Zhe, Ji, Kanfan, Yang, Xiao, Chen, Jie, Bai, Xianyong, Hou, Zhenyong, and Deng, Yuanyong

Subjects

PLASMA flow, MAGNETIC structure, SOLAR activity, MAGNETIC fields, FIBERS

Abstract

We present the observational evidence of the existence of a double-decker filament channel (FC) by using observations in extreme ultraviolet and H α wavelengths. For both FCs, the east foot-point roots in the active region (AR), while the west one roots in the remote quiet region. The bottom FC (FC1) appears as intermittent filaments. Within the AR, the FC1 appears as an S-shaped filament (F1), which consisted of two J-shaped filaments (F1S/F1N for the south/north one). For the upper one (FC2), only the east part is filled with dark plasma and visible as a small filament (F2). Its east foot-point roots around the junction of F1S and F1N. Initially, due to the recurrent reconnections, F1N and F1S link to each other and form a new filament (F3) thread by thread. Meanwhile, the heated plasma, which appears as brightening features, flows from the east foot-point of F2 to the west, and becomes invisible about 1.1 × 105 km away. The failed eruption of F1S is triggered by the reconnection, which appears as the brightening threads changing their configuration from crossed to quasiparallel in between the F1S and F3, and is confined by the upper magnetic field. Associated with the eruption, the distant invisible plasma becomes visible as a brightening feature. It continuously flows to the remote foot-point, and becomes invisible before reaching it. The brightening plasma flow outlines the skeleton of FC2 gradually. The observations show the existence of a double-decker FC, as a magnetic structure, before they appear as a brightening/dark feature when fully filled with hot/cool plasma. [ABSTRACT FROM AUTHOR]

Published

2024

35. Persistent Upflows and Downflows at Active Region Boundaries Observed by SUTRI and AIA

Author

Wu, Yuchuan, primary, Hou, Zhenyong, additional, Li, Wenxian, additional, Bai, Xianyong, additional, Song, Yongliang, additional, Yang, Xiao, additional, Hu, Ziyao, additional, Deng, Yuanyong, additional, and Ji, Kaifan, additional

Published

2024

36. Narrow-line-width UV bursts in the transition region above Sunspots observed by IRIS

Author

Hou, Zhenyong, Huang, Zhenghua, Xia, Lidong, Li, Bo, Madjarska, Maria S., Fu, Hui, Mou, Chaozhou, and Xie, Haixia

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Various small-scale structures abound in the solar atmosphere above active regions, playing an important role in the dynamics and evolution therein. We report on a new class of small-scale transition region structures in active regions, characterized by strong emissions but extremely narrow Si IV line profiles as found in observations taken with the Interface Region Imaging Spectrograph (IRIS). Tentatively named as Narrow-line-width UV bursts (NUBs), these structures are located above sunspots and comprise of one or multiple compact bright cores at sub-arcsecond scales. We found six NUBs in two datasets (a raster and a sit-and-stare dataset). Among these, four events are short-living with a duration of $\sim$10 mins while two last for more than 36 mins. All NUBs have Doppler shifts of 15--18 km/s, while the NUB found in sit-and-stare data possesses an additional component at $\sim$50 km/s found only in the C II and Mg II lines. Given that these events are found to play a role in the local dynamics, it is important to further investigate the physical mechanisms that generate these phenomena and their role in the mass transport in sunspots., Comment: 8 pages, 4 figures and 1 table, accepted for publication in ApJL

Published

2016

37. Magnetic flux supplement to coronal bright points

Author

Mou, Chaozhou, Huang, Zhenghua, Xia, Lidong, Madjarska, Maria S., Li, Bo, Fu, Hui, Jiao, Fangran, and Hou, Zhenyong

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Coronal bright points (BPs) are associated with magnetic bipolar features (MBFs) and magnetic cancellation. Here, we investigate how BP-associated MBFs form and how the consequent magnetic cancellation occurs. We analyse longitudinal magnetograms from the Helioseismic and Magnetic Imager to investigate the photospheric magnetic flux evolution of 70 BPs. From images taken in the 193 A passband of the Atmospheric Imaging Assembly (AIA) we dermine that the BPs' lifetimes vary from 2.7 to 58.8 hours. The formation of the BP MBFs is found to involve three processes, namely emergence, convergence and local coalescence of the magnetic fluxes. The formation of a MBF can involve more than one of these processes. Out of the 70 cases, flux emergence is the main process of a MBF buildup of 52 BPs, mainly convergence is seen in 28, and 14 cases are associated with local coalescence. For MBFs formed by bipolar emergence, the time difference between the flux emergence and the BP appearance in the AIA 193 \AA\ passband varies from 0.1 to 3.2 hours with an average of 1.3 hours. While magnetic cancellation is found in all 70 BPs, it can occur in three different ways: (I) between a MBF and small weak magnetic features (in 33 BPs); (II) within a MBF with the two polarities moving towards each other from a large distance (34 BPs); (III) within a MBF whose two main polarities emerge in the same place simultaneously (3 BPs). While a MBF builds up the skeleton of a BP, we find that the magnetic activities responsible for the BP heating may involve small weak fields., Comment: 20 pages, 16 figures, accepted for publication in ApJ

Published

2015

38. Detection of decayless oscillations in solar transition region loops

Author

Gao, Yuhang, primary, Hou, Zhenyong, additional, Van Doorsselaere, Tom, additional, and Guo, Mingzhe, additional

Published

2023

39. The Triggering Process of an X-class Solar Flare on a Small Quadrupolar Active Region

Author

Song, Qiao, primary, Wang, Jing-Song, additional, Zhang, Xiaoxin, additional, Chen, Hechao, additional, Yang, Shuhong, additional, Hou, Zhenyong, additional, Hou, Yijun, additional, Ye, Qian, additional, Zhang, Peng, additional, Hu, Xiuqing, additional, Dun, Jinping, additional, Zong, Weiguo, additional, Bai, Xianyong, additional, Chen, Bo, additional, He, Lingping, additional, and Song, Kefei, additional

Published

2023

40. Formation and Dynamics in an Observed Preeruptive Filament

Author

Huang, Jing, primary, Zhang, Yin, additional, Tan, Baolin, additional, Bai, Xianyong, additional, Li, Leping, additional, Hou, Zhenyong, additional, Yang, Xiao, additional, Ji, Kaifan, additional, Song, Yongliang, additional, Hu, Ziyao, additional, and Deng, Yuanyong, additional

Published

2023

41. The Impulsive Acceleration of a Solar Filament Eruption Associated with a B-class Flare

Author

Wang, Xinyue, primary, Song, Hongqiang, additional, Chen, Yao, additional, Li, Leping, additional, Hou, Zhenyong, additional, and Zheng, Ruisheng, additional

Published

2023

42. Observation of Two Splitting Processes in a Partial Filament Eruption on the Sun: The Role of Breakout Reconnection

Author

Sun, Zheng, primary, Li, Ting, additional, Tian, Hui, additional, Hou, Yijun, additional, Hou, Zhenyong, additional, Chen, Hechao, additional, Bai, Xianyong, additional, and Deng, Yuanyong, additional

Published

2023

43. A Type II Radio Burst Driven by a Blowout Jet on the Sun

Author

Hou, Zhenyong, primary, Tian, Hui, additional, Su, Wei, additional, Madjarska, Maria S., additional, Chen, Hechao, additional, Zheng, Ruisheng, additional, Bai, Xianyong, additional, and Deng, Yuanyong, additional

Published

2023

44. Traveling kink oscillations of coronal loops launched by a solar flare

Author

Li, Dong, primary, Bai, Xianyong, additional, Tian, Hui, additional, Su, Jiangtao, additional, Hou, Zhenyong, additional, Deng, Yuanyong, additional, Ji, Kaifan, additional, and Ning, Zongjun, additional

Published

2023

45. Internal Activities in a Solar Filament and Heating in Its Threads.

Author

Wei, Hengyuan, Huang, Zhenghua, Li, Chuan, Hou, Zhenyong, Qiu, Ye, Fu, Hui, Bai, Xianyong, and Xia, Lidong

Subjects

SOLAR filaments, SOLAR activity, MAGNETIC reconnection, PLASMA physics, HELIOSEISMOLOGY, SOLAR heating, SOLAR atmosphere

Abstract

Filaments are one of the most common features in the solar atmosphere and are of significance in solar, stellar, and laboratory plasma physics. Using data from the Chinese H α Solar Explorer, the Solar Upper Transition Region Imager, and the Solar Dynamics Observatory, we report on multiwavelength imaging and spectral observations of the activation of a small filament. The filament activation produces several localized dynamic brightenings, which are probably produced by internal reconnections of the braided magnetic fields in the filament. The filament expands during the activation, and its threads reconnect with the ambient magnetic fields, which leads to the formation of hot arcades or loops overlying the filament. The thermal energy of each of these localized brightenings is estimated in the order of 1025–1027 erg, and the total energy is estimated to be ∼1.77 × 1028 erg. Our observations demonstrate that the internal magnetic reconnections in the filament can lead to localized heating in the filament threads and prompt external reconnections with ambient corona structures and thus could contribute to the energy and mass transferring into the corona. [ABSTRACT FROM AUTHOR]

Published

2023

46. The Solar Upper Transition Region Imager (SUTRI) Onboard the SATech-01 Satellite

Author

Bai, Xianyong, primary, Tian, Hui, additional, Deng, Yuanyong, additional, Wang, Zhanshan, additional, Yang, Jianfeng, additional, Zhang, Xiaofeng, additional, Zhang, Yonghe, additional, Qi, Runze, additional, Wang, Nange, additional, Gao, Yang, additional, Yu, Jun, additional, He, Chunling, additional, Shen, Zhengxiang, additional, Shen, Lun, additional, Guo, Song, additional, Hou, Zhenyong, additional, Ji, Kaifan, additional, Bi, Xingzi, additional, Duan, Wei, additional, Yang, Xiao, additional, Lin, Jiaben, additional, Hu, Ziyao, additional, Song, Qian, additional, Yang, Zihao, additional, Chen, Yajie, additional, Qiao, Weidong, additional, Ge, Wei, additional, Li, Fu, additional, Jin, Lei, additional, He, Jiawei, additional, Chen, Xiaobo, additional, Zhu, Xiaocheng, additional, He, Junwang, additional, Shi, Qi, additional, Liu, Liu, additional, Li, Jinsong, additional, Xu, Dongxiao, additional, Liu, Rui, additional, Li, Taijie, additional, Feng, Zhenggong, additional, Wang, Yamin, additional, Fan, Chengcheng, additional, Liu, Shuo, additional, Guo, Sifan, additional, Sun, Zheng, additional, Wu, Yuchuan, additional, Li, Haiyu, additional, Yang, Qi, additional, Ye, Yuyang, additional, Gu, Weichen, additional, Wu, Jiali, additional, Zhang, Zhe, additional, Yu, Yue, additional, Ye, Zeyi, additional, Sheng, Pengfeng, additional, Wang, Yifan, additional, Li, Wenbin, additional, Huang, Qiushi, additional, and Zhang, Zhong, additional

Published

2023

47. Why “Solar Tsunamis” Rarely Leave Their Imprints in the Chromosphere

Author

Zheng, Ruisheng, primary, Liu, Yihan, additional, Liu, Wenlong, additional, Wang, Bing, additional, Hou, Zhenyong, additional, Feng, Shiwei, additional, Kong, Xiangliang, additional, Huang, Zhenghua, additional, Song, Hongqiang, additional, Tian, Hui, additional, Chen, Pengfei, additional, Erdélyi, Robertus, additional, and Chen, Yao, additional

Published

2023

48. Current Status and Future Perspectives of Solar Spectroscopic Observations at Extreme Ultraviolet Wavelengths

Author

BAI, Xianyong, primary, TIAN, Hui, additional, DENG, Yuan-yong, additional, CHEN, Yajie, additional, HOU, Zhenyong, additional, YANG, Zihao, additional, ZHANG, Zhiyong, additional, DUAN, Wei, additional, LI, Wenxian, additional, and GUO, Sifan, additional

Published

2023

49. Cross-loop Propagation of a Quasiperiodic Extreme-ultraviolet Wave Train Triggered by Successive Stretching of Magnetic Field Structures during a Solar Eruption

Author

Sun, Zheng, primary, Tian, Hui, additional, Chen, P. F., additional, Yao, Shuo, additional, Hou, Zhenyong, additional, Chen, Hechao, additional, and Chen, Linjie, additional

Published

2022

50. A New Post-hoc Flat Field Measurement Method for the Solar X-Ray and Extreme Ultraviolet Imager Onboard the FengYun-3E Satellite

Author

Song, Qiao, primary, Bai, Xianyong, additional, Chen, Bo, additional, Hu, Xiuqing, additional, Chen, Yajie, additional, Hou, Zhenyong, additional, Zhang, Xiaofan, additional, He, Lingping, additional, Song, Kefei, additional, Zhang, Peng, additional, Wang, Jing-Song, additional, Zhang, Xiaoxin, additional, Zong, Weiguo, additional, Dun, Jinping, additional, Tian, Hui, additional, and Deng, Yuanyong, additional

Published

2022