Your search keyword '"Prasad, Avijeet"' showing total 120 results

1. High-resolution observations of recurrent jets from an arch filament system

Author

Joshi, Reetika, van der Voort, Luc Rouppe, Schmieder, Brigitte, Moreno-Insertis, Fernando, Prasad, Avijeet, Aulanier, Guillaume, and Nóbrega-Siverio, Daniel

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Solar jets are collimated plasma ejections along magnetic field lines observed in hot (EUV jets) and cool (chromospheric surges) temperature diagnostics. Their trigger mechanisms and the relationship between hot and cool jets are still not completely understood. We aim to investigate the generation of a sequence of active region solar jets and their evolution from the photospheric to the coronal heights. Using the synergy of high spatial and temporal resolution observations by the SST, along with the SDO, we analyze a sequence of solar jets originating in a mixed polarity region between the leading and following sunspots of an active region. We use a NFFF extrapolation technique for deriving the magnetic field topology of the active region. A mixed polarity region is formed over a long period (24 hours) with persistent magnetic flux emergence. This region has been observed as an arch filament system (AFS) in chromospheric SST observations. In this region, negative polarities surrounded by positive polarities create a fan-surface with a null point at a height of 6 Mm detected in the NFFF extrapolation. SST observations in H-beta spectral line reveal a large flux rope over the AFS and moving from the North to South, causing successive EUV and cool jets to move in the East-West direction and later towards the South along the long open loops. The high resolution SST observations (0.038 arcsec per pixel) resolve the dark area observed at the jet base and reveal the existence of an AFS with an extended cool jet which may be the result of a peeling-like mechanism of the AFS. Based on the combined analysis of SST and AIA observations along with extrapolated magnetic topology, it is suggested that the magnetic reconnection site may move southward by approximately 20 Mm until it reaches a region where the open magnetic field lines are oriented North-South., Comment: 14 pages, 11 figures, accepted for publication in A&A

Published

2024

2. From eruption to post-flare rain: a 2.5D MHD model

Author

Sen, Samrat, Prasad, Avijeet, Liakh, Valeriia, and Keppens, Rony

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics

Abstract

The formation of the MFRs in the pre-flare stage, and how this leads to coronal rain in a post-eruption magnetic loop is not fully understood. We explore the formation, and eruption of MFRs, followed by the appearance of coronal rain in the post-flare loops, to understand the magnetic and thermodynamic properties of eruptive events and their multi-thermal aspects in the solar atmosphere. We perform a resistive-magnetohydrodynamic (MHD) simulation with the open-source code \texttt{MPI-AMRVAC} to explore the evolution of sheared magnetic arcades that can lead to flux rope eruptions. The system is in mechanical imbalance at the initial state, and evolves self-consistently in a non-adiabatic atmosphere under the influence of radiative losses, thermal conduction, and background heating. We use an additional level of adaptive mesh refinement to achieve the smallest cell size of $\approx 32.7$ km in each direction to reveal the fine structures in the system. The system achieves a semi-equilibrium state after a short transient evolution from its initial mechanically imbalanced condition. A series of erupting MFRs is formed due to spontaneous magnetic reconnection, across current sheets created underneath the erupting flux ropes. Gradual development of thermal imbalance is noticed at a loop top in the post-eruption phase, which leads to catastrophic cooling and formation of condensations. We obtain plasma blobs which fall down along the magnetic loop in the form of coronal rain. The dynamical and thermodynamic properties of these cool-condensations are in good agreement with observations of post-flare coronal rain. The presented simulation supports the development and eruption of multiple MFRs, and the formation of coronal rain in post-flare loops, which is one of the key aspects to reveal the coronal heating mystery in the solar atmosphere., Comment: Accepted for publication in Astronomy and Astrophysics journal. The animation associated with Figure 3 is available on request from the corresponding author. Comments are welcome

Published

2024

3. Formation of an observed eruptive flux rope above the torus instability threshold through tether-cutting magnetic reconnection

Author

Prasad, Avijeet, Kumar, Sanjay, Sterling, Alphonse C., Moore, Ronald L., Aulanier, Guillaume, Bhattacharyya, R., and Hu, Qiang

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Erupting magnetic flux ropes (MFRs) play a crucial role in producing solar flares. However, the formation of erupting MFRs in complex coronal magnetic configurations and their subsequent evolution in the flaring events are not fully understood. We performed an MHD simulation of active region NOAA 12241 to understand the formation of a rising MFR during the onset of an M6.9 flare on 2014 December 18, around 21:41 UT. The MHD simulation was initialised with an extrapolated non-force-free magnetic field generated from the photospheric vector magnetogram of the active region taken a few minutes before the flare. The initial magnetic field topology displays a pre-existing sheared arcade enveloping the polarity inversion line. The simulated dynamics exhibit the movement of the oppositely directed legs of the sheared arcade field lines towards each other due to the converging Lorentz force, resulting in the onset of tether-cutting magnetic reconnection that produces an underlying flare arcade and flare ribbons. Concurrently, an MFR above the flare arcade develops inside the sheared arcade and shows a rising motion. The MFR is found to be formed in a torus-unstable region, thereby explaining its eruptive nature. Interestingly, the location and rise of the rope are in good agreement with the corresponding observations seen in EUV channels. Furthermore, the foot points of the simulation's flare arcade match well with the location of the observed parallel ribbons of the flare. The presented simulation supports the development of the MFR by the tether-cutting magnetic reconnection inside the sheared coronal arcade during flare onset. The MFR is then found to extend along the polarity inversion line (PIL) through slip-running reconnection. The MFR's eruptive nature is ascribed both to its formation in the torus-unstable region and also to the runaway tether-cutting reconnection., Comment: 12 pages, 8 figures, accepted for publication in Astronomy & Astrophysics

Published

2023

4. Magnetohydrodynamics simulation of magnetic flux rope formation in a quadrupolar magnetic field configuration

Author

Kumar, Sanjay, Prasad, Avijeet, Nayak, Sushree S., Agarwal, Satyam, and Bhattacharyya, R.

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

Magnetic flux ropes (MFRs) play an important role in high-energetic events like solar flares and coronal mass ejections in the solar atmosphere. Importantly, solar observations suggest an association of some flaring events with quadrupolar magnetic configurations. However, the formation and subsequent evolution of MFRs in such magnetic configurations still need to be fully understood. In this paper, we present idealized magnetohydrodynamics (MHD) simulations of MFR formation in a quadrupolar magnetic configuration. A suitable initial magnetic field having a quadrupolar configuration is constructed by modifying a three-dimensional (3D) linear force-free magnetic field. The initial magnetic field contains neutral lines, which consist of X-type null points. The simulated dynamics initially demonstrate the oppositely directed magnetic field lines located across the polarity inversion lines (PILs) moving towards each other, resulting in magnetic reconnections. Due to these reconnections, four highly twisted MFRs form over the PILs. With time, the foot points of the MFRs move towards the X-type neutral lines and reconnect, generating complex magnetic structures around the neutral lines, thus making the MFR topology more complex in the quadrupolar configuration than those formed in bipolar loop systems. Further evolution reveals the non-uniform rise of the MFRs. Importantly, the simulations indicate that the pre-existing X-type null points in magnetic configurations can be crucial to the evolution of the MFRs and may lead to the observed brightenings during the onset of some flaring events in the quadrupolar configurations., Comment: 18 pages, 9 figures

Published

2023

5. Coronal Magnetic Field Extrapolation and Topological Analysis of Fine-Scale Structures during Solar Flare Precursors

Author

He, Wen, Hu, Qiang, Jing, Ju, Wang, Haimin, Jiang, Chaowei, Nayak, Sushree S., and Prasad, Avijeet

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics

Abstract

Magnetic field plays an important role in various solar eruptions like flares, coronal mass ejections, etc. The formation and evolution of characteristic magnetic field topology in solar eruptions are critical problems that will ultimately help us understand the origination of these eruptions in the solar source regions. With the development of advanced techniques and instruments, observations with higher resolutions in different wavelengths and fields of view have provided more quantitative information for finer structures. So it is essential to improve our method to study the magnetic field topology in the solar source regions by taking advantage of high-resolution observations. In this study, we employ a nonlinear force-free field (NLFFF) extrapolation method based on a nonuniform grid setting for an M-class flare eruption event (SOL2015-06-22T17:39) with embedded magnetograms from the Solar Dynamics Observatory (SDO) and the Goode Solar Telescope (GST). The extrapolation results employing the embedded magnetogram for the bottom boundary are obtained by maintaining the native resolutions of the corresponding GST and SDO magnetograms. We compare the field line connectivity with the simultaneous GST/H$\alpha$ and SDO/AIA observations for fine-scale structures associated with precursor brightenings. Then we perform a topological analysis of the field line connectivity corresponding to fine-scale magnetic field structures based on the extrapolation results. The results indicate that by combining the high-resolution GST magnetogram with a larger HMI magnetogram, the derived magnetic field topology is consistent with a scenario of magnetic reconnection among sheared field lines across the main polarity inversion line during solar flare precursors., Comment: 17 pages, 9 figures, 2 tables, submitted to ApJ

Published

2023

6. Evolution of magnetic fields and energy release processes during homologous eruptive flares

Author

Sahu, Suraj, Joshi, Bhuwan, Prasad, Avijeet, and Cho, Kyung-Suk

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We explore the processes of repetitive build-up and explosive release of magnetic energy together with the formation of magnetic flux ropes that eventually resulted into three homologous eruptive flares of successively increasing intensities (i.e., M2.0, M2.6, and X1.0). The flares originated from NOAA active region 12017 during 2014 March 28-29. EUV observations and magnetogram measurements together with coronal magnetic field modeling suggest that the flares were triggered by the eruption of flux ropes embedded by a densely packed system of loops within a small part of the active region. In X-rays, the first and second events show similar evolution with single, compact sources, while the third event exhibits multiple emission centroids with a set of strong non-thermal conjugate sources at 50-100 keV during the HXR peak. The photospheric magnetic field over an interval of approximately 44 hr encompassing the three flares undergoes important phases of emergence and cancellation processes together with significant changes near the polarity inversion lines within the flaring region. Our observations point toward the tether-cutting mechanism as the plausible triggering process of the eruptions. Between the second and third event, we observe a prominent phase of flux emergence which temporally correlates with the build-up phase of free magnetic energy in the active region corona. In conclusion, our analysis reveals an efficient coupling between the rapidly evolving photospheric and coronal magnetic fields in the active region that led to a continued phase of the build-up of free energy, resulting into the homologous flares of successively increasing intensities., Comment: Accepted for publication in 'The Astrophysical Journal'

Published

2022

7. Magnetohydrodynamics evolution of three-dimensional magnetic null in NOAA active region 11515 initiated using non-force-free field extrapolation

Author

Kumar, Sanjay, Prasad, Avijeet, Sarkar, Ranadeep, and Bhattacharyya, Ramit

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Magnetohydrodynamics simulation of active region NOAA 11515 is performed to examine the initiation of the M5.6 flaring event that starts around 10:43 UT on 2012 July 2. The simulation is conducted using an extrapolated non-force-free magnetic field generated from the photospheric vector magnetogram of the active region as the initial magnetic field. The magnetic field shows the presence of a three-dimensional (3D) magnetic null with the corresponding dome overlying a filament and a low-lying magnetic flux rope, observed in 304~\AA~ and 131~\AA~ respectively. The simulated dynamics, triggered by the initial Lorentz force, lead to the bifurcations of the flux rope, which is similar to the observed bifurcation in the 131 \AA~ brightenings. Additionally, the rope exhibits a rise and reconnects at the 3D null. These reconnections convert field lines of the rope into the anchored outer spine of the 3D null -- explaining the occurrence of a nearby confined C-class flare. Further, the results show that the field lines of the flux rope reach the vicinity of the filament and become non-parallel to the field lines of the filament. This initiates the reconnections between the rope and the field lines of the filament -- activating the filament for the eruption. This interesting interaction of the flux rope and filament seems to contribute to the onset of the M-class flare., Comment: 10 Figures

Published

2022

8. Validation and interpretation of three-dimensional configuration of a magnetic cloud flux rope

Author

Hu, Qiang, Zhu, Chunming, He, Wen, Qiu, Jiong, Jian, Lan K., and Prasad, Avijeet

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics, Physics - Space Physics

Abstract

One "strong" magnetic cloud (MC) with the magnetic field magnitude reaching $\sim$ 40 nT at 1 au during 2012 June 16-17 is examined in association with a pre-existing magnetic flux rope (MFR) identified on the Sun. The MC is characterized by a quasi-three dimensional (3D) flux rope model based on in situ measurements from the Wind spacecraft. The magnetic flux contents and other parameters are quantified. In addition, a correlative study with the corresponding measurements of the same structure crossed by the Venus Express (VEX) spacecraft at a heliocentric distance 0.7 au and with an angular separation $\sim 6^\circ$ in longitude is performed to validate the MC modeling results. The spatial variation between the Wind and VEX magnetic field measurements is attributed to the 3D configuration of the structure as featured by a knotted bundle of flux. The comparison of the magnetic flux contents between the MC and the source region on the Sun indicates that the 3D reconnection process accompanying an M1.9 flare may correspond to the magnetic reconnection between the field lines of the pre-existing MFR rooted in the opposite polarity footpoints. Such a process reduces the amount of the axial magnetic flux in the erupted flux rope, by approximately 50\%, in this case., Comment: Submitted to ApJ

Published

2022

9. The outcomes of total knee arthroplasty following the incidental finding of tuberculosis and its treatment: A prospective study

Author

Bhattacharjee, Sujoy, Prasad, Avijeet, Ahlawat, Akhil, and R B, Pavan

Published

2024

10. Quantitative Characterization of Magnetic Flux Rope Properties for Two Solar Eruption Events

Author

He, Wen, Hu, Qiang, Jiang, Chaowei, Qiu, Jiong, and Prasad, Avijeet

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

In order to bridge the gap between heliospheric and solar observations of coronal mass ejections (CMEs), one of the key steps is to improve the understanding of their corresponding magnetic structures like the magnetic flux ropes (MFRs). But it remains a challenge to confirm the existence of a coherent MFR before or upon the CME eruption on the Sun and to quantitatively characterize the CME-MFR due to the lack of direct magnetic field measurement in the corona. In this study, we investigate the MFR structures, originating from two active regions (ARs), AR 11719 and AR 12158, and estimate their magnetic properties quantitatively. We perform the nonlinear force-free field extrapolations with preprocessed photospheric vector magnetograms. In addition, remote-sensing observations are employed to find indirect evidence of MFRs on the Sun and to analyze the time evolution of magnetic reconnection flux associated with the flare ribbons during the eruption. A coherent "pre-existing" MFR structure prior to the flare eruption is identified quantitatively for one event from the combined analysis of the extrapolation and observation. Then the characteristics of MFRs for two events on the Sun before and during the eruption, forming the CME-MFR, including the axial magnetic flux, field-line twist, and reconnection flux, are estimated and compared with the corresponding in situ modeling results. We find that the magnetic reconnection associated with the accompanying flares for both events injects significant amount of flux into the erupted CME-MFRs., Comment: 28 pages, 10 figures, 3 tables, submitted to ApJ

Published

2022

11. Comparison of the Hall Magnetohydrodynamics and Magnetohydrodynamics evolution of a flaring solar active region

Author

Bora, Kamlesh, Bhattacharyya, Ramit, Prasad, Avijeet, Joshi, Bhuwan, and Hu, Qiang

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

This work analyzes the Hall magnetohydrodynamics (HMHD) and magnetohydrodynamics (MHD) numerical simulations of a flaring solar active region as a testbed while idealizing the coronal Alfv\'en speed to be of two orders of magnitude lesser. HMHD supports faster magnetic reconnection and shows richer complexity in magnetic field line evolution compared to the MHD. The magnetic reconnections triggering the flare are explored by numerical simulations augmented with relevant multi-wavelength observations. The initial coronal magnetic field is constructed by non-force-free extrapolation of photospheric vector magnetic field. Magnetic structure involved in the flare is identified to be a flux rope, with its overlying magnetic field lines constituting the quasi-separatrix layers (QSLs) along with a three-dimensional null point and a null line. Compared to the MHD simulation, the HMHD simulation shows a higher and faster ascend of the rope together with the overlying field lines, which further reconnect at the QSL located higher up in the corona. The foot points of the field lines match better with the observations for the HMHD case with the central part of the flare ribbon located at the chromosphere. Additionally, field lines are found to rotate in a circular pattern in the HMHD, whereas no such rotation is seen in the MHD results. Interestingly, plasma is also observed to be rotating in a co-spatial chromospheric region, which makes the HMHD simulation more credible. Based on the aforementioned agreements, HMHD simulation is found to agree better with observations and, thus, opens up a novel avenue to explore., Comment: 31 pages, 17 figures (accepted for publication in The Astrophysical Journal)

Published

2021

12. Heating of the solar chromosphere in a sunspot light bridge by electric currents

Author

Louis, Rohan E., Prasad, Avijeet, Beck, Christian, Choudhary, Debi Prasad, and Yalim, Mehmet S.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

Context: Resistive Ohmic dissipation has been suggested as a mechanism for heating the solar chromosphere, but few studies have established this association. Aim: We aim to determine how Ohmic dissipation by electric currents can heat the solar chromosphere. Methods: We combine high-resolution spectroscopic Ca II data from the Dunn Solar Telescope and vector magnetic field observations from the Helioseismic and Magnetic Imager (HMI) to investigate thermal enhancements in a sunspot light bridge. The photospheric magnetic field from HMI was extrapolated to the corona using a non-force-free field technique that provided the three-dimensional distribution of electric currents, while an inversion of the chromospheric Ca II line with a local thermodynamic equilibrium and a nonlocal thermodynamic equilibrium spectral archive delivered the temperature stratifications from the photosphere to the chromosphere. Results: We find that the light bridge is a site of strong electric currents, of about 0.3 A/m^2 at the bottom boundary, which extend to about 0.7 Mm while decreasing monotonically with height. These currents produce a chromospheric temperature excess of about 600-800 K relative to the umbra. Only the light bridge, where relatively weak and highly inclined magnetic fields emerge over a duration of 13 hr, shows a spatial coincidence of thermal enhancements and electric currents. The temperature enhancements and the Cowling heating are primarily confined to a height range of 0.4-0.7 Mm above the light bridge. The corresponding increase in internal energy of 200 J/m^3 can be supplied by the heating in about 10 min. Conclusions: Our results provide direct evidence for currents heating the lower solar chromosphere through Ohmic dissipation., Comment: Accepted for publication in Astronomy & Astrophysics Letters: 7 pages, 5 figures

Published

2021

13. Are the brightest coronal loops always rooted in mixed-polarity magnetic flux?

Author

Tiwari, Sanjiv K., Evans, Caroline L., Panesar, Navdeep K., Prasad, Avijeet, and Moore, Ronald L.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

A recent study demonstrated that freedom of convection and strength of magnetic field in the photospheric feet of active-region (AR) coronal loops, together, can engender or quench heating in them. Other studies stress that magnetic flux cancellation at the loop-feet potentially drives heating in loops. We follow 24-hour movies of a bipolar AR, using EUV images from SDO/AIA and line-of-sight (LOS) magnetograms from SDO/HMI, to examine magnetic polarities at the feet of 23 of the brightest coronal loops. We derived FeXVIII emission (hot-94) images (using the Warren et al. method) to select the hottest/brightest loops, and confirm their footpoint locations via non-force-free field extrapolations. From 6"$\times$6" boxes centered at each loop foot in LOS magnetograms we find that $\sim$40\% of the loops have both feet in unipolar flux, and $\sim$60\% of the loops have at least one foot in mixed-polarity flux. The loops with both feet unipolar are $\sim$15\% shorter lived on average than the loops having mixed-polarity foot-point flux, but their peak-intensity averages are equal. The presence of mixed-polarity magnetic flux in at least one foot of majority of the loops suggests that flux cancellation at the footpoints may drive most of the heating. But, the absence of mixed-polarity magnetic flux (to the detection limit of HMI) in $\sim$40\% of the loops suggests that flux cancellation may not be necessary to drive heating in coronal loops -- magnetoconvection and field strength at both loop feet possibly drive much of the heating, even in the cases where a loop foot presents mixed-polarity magnetic flux., Comment: 11 pages, 5 figures

Published

2021

14. Magnetic reconnections in the presence of three-dimensional magnetic nulls and quasi-separatrix layers

Author

Kumar, Sanjay, Nayak, Sushree S., Prasad, Avijeet, and Bhattacharyya, Ramit

Subjects

Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics

Abstract

Three-dimensional (3D) magnetohydrodynamic simulations are carried out to explore magnetic reconnections in the presence of 3D magnetic nulls and quasi-separatrix layers (QSLs). The initial magnetic fields are created by superposing uniform vertical magnetic fields of two different magnitudes on a linear force-free field. The interior of the numerical box contains two 3D nulls with separatrix domes separated by a quasi-separator (or hyperbolic flux tube) with QSLs. In the first simulation, the uniform vertical field is so large that the nulls are located at low heights and the domes are separate. Initially unbalanced Lorentz forces drive rotational flows that form strong electric currents and strong torsional fan reconnection at the 3D nulls and weak QSL reconnection at the hyperbolic flux tube. Flipping or slipping of field lines is observed in both cases. In the second simulation, with a weaker vertical field and larger domes, the separatrix surfaces meet at the central quasi-separator and their rotation drives stronger QSL reconnection than before., Comment: 24 pages, 14 figures, Accepted for the publication in Solar Physics

Published

2020

15. Magnetohydrodynamic Simulation of Magnetic Null-point Reconnections and Coronal dimmings during the X2.1 flare in NOAA AR 11283

Author

Prasad, Avijeet, Dissauer, Karin, Hu, Qiang, Bhattacharyya, R., Veronig, Astrid M., Kumar, Sanjay, and Joshi, Bhuwan

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The magnetohydrodynamics of active region NOAA 11283 is simulated using an initial non-force-free magnetic field extrapolated from its photospheric vector magnetogram. We focus on the magnetic reconnections at a magnetic null point that participated in the X2.1 flare on 2011 September 6 around 22:21 UT (SOL2011-09-06T22:21X2.1) followed by the appearance of circular flare ribbons and coronal dimmings. The initial magnetic field from extrapolation displays a three-dimensional (3D) null topology overlying a sheared arcade. Prior to the flare, magnetic loops rise due to the initial Lorentz force, and reconnect at the 3D null, leading to expansion and loss of confined plasma that produce the observed pre-flare coronal dimmings. Further, the simulated dynamics documents the transfer of twist from the arcade to the overlying loops through reconnections, developing a flux rope. The non-parallel field lines comprising the rope and lower-lying arcades form an X-type geometry. Importantly, the simultaneous reconnections at the 3D null and the X-type geometry can explain the observed circular and parallel flare ribbons. Reconnections at the 3D null transform closed inner spine field lines into open field lines of the outer spine. The footpoints of these open field lines correspond to a ring-shaped coronal dimming region, tracing the dome. Further, the flux rope bifurcates because of these reconnections which also results in the generation of open magnetic field lines. The plasma loss along the open field lines can potentially explain the observed coronal dimming., Comment: 29 pages, 13 figures, accepted for publication in The Astrophysical Journal

Published

2020

16. An Eruptive Circular-ribbon Flare with Extended Remote Brightenings

Author

Liu, Chang, Prasad, Avijeet, Lee, Jeongwoo, and Wang, Haimin

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We study an eruptive X1.1 circular-ribbon flare on 2013 November 10, combining multiwavelength observations with a coronal field reconstruction using a non-force-free field method. In the first stage, a filament forms via magnetic reconnection between two mildly twisted sheared arcades, which are embedded under the fan dome associated with a null point. This reconnection seems to be driven by photospheric shearing and converging flows around the inner two arcade footpoints, consistent with the flare-related changes of transverse field. The southern portion of the filament rises upward due to torus instability and pushes against the null point. The induced null point reconnection then generates the circular ribbon and the initial remote brightening in the west, as accelerated electrons precipitate along the fan and propagate outward along quasi-separatix surfaces with high values of the squashing factor (Q) in the envelope fields, which have a curtain-like shape here. In the second stage, the southern end of the flux rope breaks away from the surface, sequentially disrupts the dome and overlying fields, and erupts in a whipping-like fashion to become a partial halo coronal mass ejection. This leads to an enhanced flare emission and fast-moving remote brightenings at the footpoints of the magnetic curtain, which span a remarkably broad region and are also associated with coronal dimmings. This is a rare example of eruptive circular-ribbon flares, in which the evolution of a flux rope from its formation to successful eruption out of the dome and the resulting unusually extended remote brightenings are completely observed., Comment: 12 pages, 7 figures, Accepted to ApJ

Published

2020

17. A data-driven MHD model of the weakly-ionized chromosphere

Author

Yalim, Mehmet Sarp, Prasad, Avijeet, Pogorelov, Nikolai, Zank, Gary, and Hu, Qiang

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The physics of the solar chromosphere is complex from both theoretical and modeling perspectives. The plasma temperature from the photosphere to corona increases from ~5,000 K to ~1 million K over a distance of only ~10,000 km from the chromosphere and the transition region. Certain regions of the solar atmosphere have sufficiently low temperature and ionization rates to be considered as weakly-ionized. In particular, this is true at the lower chromosphere. In this paper, we present an overview of our data-driven magnetohydrodynamics model for the weakly-ionized chromosphere and show a benchmark result. It utilizes the Cowling resistivity which is orders of magnitude greater than the Coulomb resistivity. Ohm's law therefore includes anisotropic dissipation. We investigate the effects of the Cowling resistivity on heating and magnetic reconnection in the chromosphere as the flare-producing active region (AR) 11166 evolves. In particular, we analyze a C2.0 flare emerging from AR11166 and find a normalized reconnection rate of 0.12., Comment: 14 pages, 4 figures, Journal of Physics Conference Series - Proceedings of the 19th Annual International Astrophysics Conference, Santa Fe, NM, March 9-13, 2020 (accepted)

Published

2020

18. Effects of Cowling Resistivity in the Weakly-Ionized Chromosphere

Author

Yalim, Mehmet Sarp, Prasad, Avijeet, Pogorelov, Nikolai, Zank, Gary, and Hu, Qiang

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

The physics of the solar chromosphere is complex from both theoretical and modeling perspectives. The plasma temperature from the photosphere to corona increases from ~5,000 K to ~1 million K over a distance of only ~10,000 km from the chromosphere and the transition region. Certain regions of the solar atmosphere have sufficiently low temperature and ionization rates to be considered as weakly-ionized. In particular, this is true at the lower chromosphere. As a result, the Cowling resistivity is orders of magnitude greater than the Coulomb resistivity. Ohm's law therefore includes anisotropic dissipation. To evaluate the Cowling resistivity, we need to know the external magnetic field strength and to estimate the neutral fraction as a function of the bulk plasma density and temperature. In this study, we determine the magnetic field topology using the non-force-free field (NFFF) extrapolation technique based on SDO/HMI SHARP vector magnetogram data, and the stratified density and temperature profiles from the Maltby-M umbral core model for sunspots. We investigate the variation and effects of Cowling resistivity on heating and magnetic reconnection in the chromosphere as the flare-producing active region (AR) 11166 evolves. In particular, we analyze a C2.0 flare emerging from AR11166 and find a normalized reconnection rate of 0.051., Comment: 15 pages, 5 figures, The Astrophysical Journal Letters (in press)

Published

2020

19. A Solar Magnetic-fan Flaring Arch Heated by Non-thermal Particles and Hot Plasma from an X-ray Jet Eruption

Author

Lee, Kyoung-Sun, Hara, Hirohisa, Watanabe, Kyoko, Joshi, Anand D., Brooks, David H., Imada, Shinsuke, Prasad, Avijeet, Dang, Phillip, Shimizu, Toshifumi, Savage, Sabrina L., Moore, Ronald, Panesar, Navdeep K., and Reep, Jeffrey W.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We have investigated an M1.3 limb flare, which develops as a magnetic loop/arch that fans out from an X-ray jet. Using Hinode/EIS, we found that the temperature increases with height to a value of over 10$^{7}$ K at the loop-top during the flare. The measured Doppler velocity (redshifts of 100$-$500 km s$^{-1}$) and the non-thermal velocity ($\geq$100 km s$^{-1}$) from Fe XXIV also increase with loop height. The electron density increases from $0.3\times10^{9}$ cm$^{-3}$ early in the flare rise to $1.3\times10^{9}$ cm$^{-3}$ after the flare peak. The 3-D structure of the loop derived with STEREO/EUVI indicates that the strong redshift in the loop-top region is due to upflowing plasma originating from the jet. Both hard X-ray and soft X-ray emission from RHESSI were only seen as footpoint brightenings during the impulsive phase of the flare, then, soft X-ray emission moves to the loop-top in the decay phase. Based on the temperature and density measurements and theoretical cooling models, the temperature evolution of the flare arch is consistent with impulsive heating during the jet eruption followed by conductive cooling via evaporation and minor prolonged heating in the top of the fan loop. Investigating the magnetic field topology and squashing factor map from SDO/HMI, we conclude that the observed magnetic-fan flaring arch is mostly heated from low atmospheric reconnection accompanying the jet ejection, instead of from reconnection above the arch as expected in the standard flare model., Comment: 55 pages, 21 Figures, accepted for publication in ApJ

Published

2020

20. Identification of Pre-flare Processes and Their Possible Role in Driving a Large-scale Flux Rope Eruption with Complex M-class Flare in the Active Region NOAA 12371

Author

Mitra, Prabir K., Joshi, Bhuwan, and Prasad, Avijeet

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

In this article, we study the origin of precursor flare activity and investigate its role towards triggering the eruption of a flux rope which resulted into a dual-peak M-class flare (SOL2015-06-21T02:36) in the active region NOAA 12371. The flare evolved in two distinct phases with peak flux levels of M2.1 and M2.6 at an interval of $\approx$54 min. The active region exhibited striking moving magnetic features (MMFs) along with sunspot rotation. Non-linear force free field (NLFFF) modelling of the active region corona reveals a magnetic flux rope along the polarity inversion line in the trailing sunspot group which is observationally manifested by the co-spatial structures of an active region filament and a hot channel identified in the 304 and 94 \AA\ images, respectively, from the Atmospheric Imaging Assembly (AIA). The active region underwent a prolonged phase of flux enhancement followed by a relatively shorter period of flux cancellation prior to the onset of the flare which led to the build up and activation of the flux rope. Extreme ultra-violet (EUV) images reveal localised and structured pre-flare emission, from the region of MMFs, adjacent to the location of the main flare. Our analysis reveals strong, localised regions of photospheric currents of opposite polarities at the precursor location, thereby making the region susceptible to small-scale magnetic reconnection. Precursor reconnection activity from this location most likely induced a slipping reconnetion towards the northern leg of the hot channel which led to the destabilization of the flux rope. The application of magnetic virial theorem suggests that there was an overall growth of magnetic free energy in the active region during the prolonged pre-flare phase which decayed rapidly after the hot channel eruption and its successful transformation into a halo coronal mass ejection (CME)., Comment: 31 pages, 14 figures, 1 table. This is a pre-print of an article published in Solar Physics. The final authenticated version is available online at: https://doi.org/10.1007/s11207-020-1596-2

Published

2020

21. Three-dimensional magnetic field structure of a flux emerging region in the solar atmosphere

Author

Yadav, Rahul, Rodríguez, J. de la Cruz, Baso, C. J. Díaz, Prasad, Avijeet, Libbrecht, Tine, Robustini, Carolina, and Ramos, A. Asensio

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

We analyze high-resolution spectropolarimetric observations of a flux emerging region (FER) in order to understand its magnetic and kinematic structure. Our spectropolarimetric observations in the He I 1083.0 nm spectral region of a FER are recorded with GRIS at the 1.5 m aperture GREGOR telescope. A Milne-Eddington based inversion code was employed to extract the photospheric information of the Si I spectral line, whereas the He I triplet line was analyzed with the Hazel inversion code, which takes into account the joint action of the Hanle and the Zeeman effect. The spectropolarimetric analysis of Si I line displays a complex magnetic structure near the vicinity of FER. Moreover, we find supersonic downflows of 40 km/sec appears near the footpoints of loops connecting two pores of opposite polarity, whereas a strong upflows of 22 km/sec appears near the apex of the loops. Furthermore, non-force-free field extrapolations were performed separately at two layers in order to understand the magnetic field topology of the FER. We determine, using extrapolations from the photosphere and the observed chromospheric magnetic field, that the average formation height of the He triplet line is 2 Mm from the solar surface. The reconstructed loops using photospheric extrapolations along an arch filament system have a maximum height of 10.5 Mm from the solar surface with a foot-points separation of 19 Mm, whereas the loops reconstructed using chromospheric extrapolations are around 8.4 Mm high from the solar surface with a foot-point separation of 16 Mm at the chromospheric height. The magnetic topology in the FER suggests the presence of small-scale loops beneath the large loops. Under suitable conditions, due to magnetic reconnection, these loops can trigger various heating events in the vicinity of the FER., Comment: 14 pages, 13 figure, 1 table, accepted for publication in A&A

Published

2019

22. Successive flux rope eruptions from $\delta$-Sunspots region of NOAA 12673 and associated X-class eruptive flares on 2017 September 6

Author

Mitra, Prabir K., Joshi, Bhuwan, Prasad, Avijeet, Veronig, Astrid M., and Bhattacharyya, R.

Subjects

Astrophysics - Solar and Stellar Astrophysics

Abstract

In this paper, we present a multi-wavelength analysis of two X-class solar eruptive flares of classes X2.2 and X9.3 that occurred in the sigmoidal active region NOAA 12673 on 2017 September 6, by combining observations of Atmospheric Imaging Assembly and Helioseismic Magnetic Imager instruments on board the Solar Dynamics Observatory. On the day of the reported activity, the photospheric structure of the active region displayed a very complex network of $\delta$-sunspots that gave rise to the formation of a coronal sigmoid observed in the hot EUV channels. Both X-class flares initiated from the core of the sigmoid sequentially within an interval of $\sim$3 hours and progressed as a single "sigmoid--to--arcade" event. Differential emission measure analysis reveals strong heating of plasma at the core of the active region right from the pre-flare phase which further intensified and spatially expanded during each event. The identification of a pre-existing magnetic null by non-force-free-field modeling of the coronal magnetic fields at the location of early flare brightenings and remote faint ribbon-like structures during the pre-flare phase, which were magnetically connected with the core region, provide support for the breakout model of solar eruption. The magnetic extrapolations also reveal flux rope structures prior to both flares which are subsequently supported by the observations of the eruption of hot EUV channels. The second X-class flare diverged from the standard flare scenario in the evolution of two sets of flare ribbons, that are spatially well separated, providing firm evidence of magnetic reconnections at two coronal heights., Comment: 24 pages, 13 figures. Accepted for publication by The Astrophysical Journal (ApJ)

Published

2018

23. Coronal Magnetic Field Extrapolation and Topological Analysis of Fine-scale Structures during Solar Flare Precursors

Author

He, Wen, primary, Jing, Ju, additional, Wang, Haimin, additional, Nayak, Sushree S., additional, and Prasad, Avijeet, additional

Published

2023

24. Magnetic Reconnections in the Presence of Three-Dimensional Magnetic Nulls and Quasi-Separatrix Layers

Author

Kumar, Sanjay, Nayak, Sushree S., Prasad, Avijeet, and Bhattacharyya, Ramit

Published

2021

25. Understanding the heating mechanism of the solar active region atmosphere in chromosphere

Author

Yalim, Mehmet Sarp, primary, Zank, Gary, additional, Beck, Christian, additional, Choudhary, Debi Prasad, additional, Prasad, Avijeet, additional, Hu, Qiang, additional, and Frisse, Makayla, additional

Published

2023

26. Exposed versus Buried Kirschner Wires Used in Displaced Pediatric Fractures of Lateral Condyle of Humerus

Author

Prasad, Avijeet, Mishra, Puneet, Aggarwal, Aditya N., Chadha, Manish, Pandey, Rohit, and Anshuman, Rahul

Published

2018

27. Testing Quantum Effects of Gravity and Dark Energy at Laboratory Scales

Author

Arun, Kenath, primary, Sivaram, Chandra, additional, and Prasad, Avijeet, additional

Published

2023

28. Evolution of Magnetic Fields and Energy Release Processes during Homologous Eruptive Flares

Author

Sahu, Suraj, primary, Joshi, Bhuwan, additional, Prasad, Avijeet, additional, and Cho, Kyung-Suk, additional

Published

2023

29. Gravity of Negative Mass: Some Subtle Aspects and Implications

Author

Sivaram, Chandra, primary, Arun, Kenath, additional, and Prasad, Avijeet, additional

Published

2023

30. Magnetohydrodynamics evolution of three-dimensional magnetic null in NOAA active region 11515 initiated using non-force-free field extrapolation

Author

Kumar, Sanjay, primary, Prasad, Avijeet, additional, Sarkar, Ranadeep, additional, and Bhattacharyya, Ramit, additional

Published

2022

31. Quantitative Characterization of Magnetic Flux Rope Properties for Two Solar Eruption Events

Author

He, Wen, primary, Hu, Qiang, additional, Jiang, Chaowei, additional, Qiu, Jiong, additional, and Prasad, Avijeet, additional

Published

2022

32. Pathological Femoral Shaft Fracture With McCune-Albright Syndrome With Hyperthyroidism Managed With Oral Alendronate: A Case Report

Author

Bansal, Kuldeep, primary, Prasad, Avijeet, additional, Singh, Sumedha, additional, Chauhan, Ankita, additional, and Singla, Shubham, additional

Published

2022

33. Validation and Interpretation of a Three-dimensional Configuration of a Magnetic Cloud Flux Rope

Author

Hu, Qiang, primary, Zhu, Chunming, additional, He, Wen, additional, Qiu, Jiong, additional, Jian, Lan K., additional, and Prasad, Avijeet, additional

Published

2022

34. Comparison of the Hall Magnetohydrodynamics and Magnetohydrodynamics Evolution of a Flaring Solar Active Region

Author

Bora, K., primary, Bhattacharyya, R., additional, Prasad, Avijeet, additional, Joshi, Bhuwan, additional, and Hu, Qiang, additional

Published

2022

35. Gravity of Negative Mass: Some Subtle Aspects and Implications.

Author

Sivaram, Chandra, Arun, Kenath, and Prasad, Avijeet

Subjects

GRAVITATIONAL interactions, GENERAL relativity (Physics), DARK energy, BLACK holes, ASTROPHYSICS

Abstract

The gravitational interaction has mass of only one sign as the source that is conventionally taken to be positive. The existence of negative mass is not precluded in either Newtonian gravity or general relativity. Negative masses have been invoked in many recent papers to understand the dominance of repulsive dark energy that is accelerating the universe. Here we discuss the various gravitating properties of negative mass particles and their implications for black holes, cosmology, and fundamental physics. Inconsistencies in the earlier works are also discussed. We study the possibility of such negative mass particles accounting for the accelerated expansion of the universe. We set constraints on the density of these negative mass particles based on astrophysical observations. [ABSTRACT FROM AUTHOR]

Published

2022

36. Heating of the solar chromosphere in a sunspot light bridge by electric currents

Author

Louis, Rohan E., primary, Prasad, Avijeet, additional, Beck, Christian, additional, Choudhary, Debi P., additional, and Yalim, Mehmet S., additional

Published

2021

37. Testing Quantum Effects of Gravity and Dark Energy at Laboratory Scales

Author

Sivaram, C, primary, Kenath, Arun, additional, and Prasad, Avijeet, additional

Published

2021

38. Are the Brightest Coronal Loops Always Rooted in Mixed-polarity Magnetic Flux?

Author

Tiwari, Sanjiv K., primary, Evans, Caroline L., additional, Panesar, Navdeep K., additional, Prasad, Avijeet, additional, and Moore, Ronald L., additional

Published

2021

39. Polarization model for the multi-application telescope at the Udaipur Solar Observatory.

Author

Anche, Ramya M., primary, Ranganathan, M., additional, Mathew, Shibu K., additional, Sankarasubramanian, K., additional, Anupama, Gadiyara C., additional, Bireddy, Ramya, additional, Prasad, Avijeet, additional, Yadav, Rahul, additional, and Ankala, Raja Bayanna, additional

Published

2020

40. Magnetohydrodynamic Simulation of Magnetic Null-point Reconnections and Coronal Dimmings during the X2.1 Flare in NOAA AR 11283

Author

Prasad, Avijeet, primary, Dissauer, Karin, additional, Hu, Qiang, additional, Bhattacharyya, R., additional, Veronig, Astrid M., additional, Kumar, Sanjay, additional, and Joshi, Bhuwan, additional

Published

2020

41. Desmoid tumour of the distal forearm involving the distal radioulnar joint

Author

Sehgal, Apoorv, primary, Shahi, Pratyush, additional, Prasad, Avijeet, additional, and Bhagirathi Mallikarjunaswamy, Manoj, additional

Published

2020

42. A data-driven MHD model of the weakly-ionized chromosphere

Author

Sarp Yalim, Mehmet, primary, Prasad, Avijeet, additional, Pogorelov, Nikolai, additional, Zank, Gary, additional, and Hu, Qiang, additional

Published

2020

43. An Eruptive Circular-ribbon Flare with Extended Remote Brightenings

Author

Liu, Chang, primary, Prasad, Avijeet, additional, Lee, Jeongwoo, additional, and Wang, Haimin, additional

Published

2020

44. Extraosseus Ewing's Sarcoma of the Forearm

Author

Bansal, Kuldeep, primary, Prasad, Avijeet, additional, Shahi, Pratyush, additional, Sehgal, Apoorv, additional, and Kamal, Sushil, additional

Published

2020

45. Non-Detection of Dark Matter Particles: A Case for Alternate Theories of Gravity

Author

Kenath, Arun, primary, Sivaram, C, additional, Prasad, Avijeet, additional, and Rebecca, Louise, additional

Published

2020

46. A Solar Magnetic-fan Flaring Arch Heated by Nonthermal Particles and Hot Plasma from an X-Ray Jet Eruption

Author

Lee, Kyoung-Sun, primary, Hara, Hirohisa, additional, Watanabe, Kyoko, additional, Joshi, Anand D., additional, Brooks, David H., additional, Imada, Shinsuke, additional, Prasad, Avijeet, additional, Dang, Phillip, additional, Shimizu, Toshifumi, additional, Savage, Sabrina L., additional, Moore, Ronald, additional, Panesar, Navdeep K., additional, and Reep, Jeffrey W., additional

Published

2020

47. Incomplete primary hypertrophic osteoarthropathy

Author

Prasad, Avijeet, primary, Shahi, Pratyush, additional, Sehgal, Apoorv, additional, and Bhagirathi Mallikarjunaswamy, Manoj, additional

Published

2020

48. Giant Cell Tumor of the Calcaneus

Author

Batheja, Dheeraj, primary, Sehgal, Apoorv, additional, Prasad, Avijeet, additional, Shahi, Pratyush, additional, and Bansal, Kuldeep, additional

Published

2020

49. Identification of Pre-flare Processes and Their Possible Role in Driving a Large-scale Flux Rope Eruption with Complex M-class Flare in the Active Region NOAA 12371

Author

Mitra, Prabir K., primary, Joshi, Bhuwan, additional, and Prasad, Avijeet, additional

Published

2020

50. Three-dimensional magnetic field structure of a flux-emerging region in the solar atmosphere

Author

Yadav, Rahul, primary, de la Cruz Rodríguez, Jaime, additional, Díaz Baso, Carlos José, additional, Prasad, Avijeet, additional, Libbrecht, Tine, additional, Robustini, Carolina, additional, and Asensio Ramos, Andrés, additional

Published

2019