Your search keyword '"Natsuha Kuroda"' showing total 16 results

1. Element Abundances in Impulsive Solar Energetic Particle Events

Author

J. Martin Laming and Natsuha Kuroda

Subjects

Solar energetic particles, Solar particle emission, Chemical abundances, Overabundances, Alfven waves, Astrophysics, QB460-466

Abstract

We outline and discuss a model for the enhanced abundances of trans-Fe elements in impulsive solar energetic particle (SEP) events, where large mass-dependent abundance enhancements are frequently seen. It comes about as a variation of the ponderomotive force model for the first ionization potential (FIP) effect, i.e., the increase in coronal abundance of elements like Fe, Mg, and Si that are ionized in the solar chromosphere relative to those that are neutral. In this way, the fractionation region is placed in the chromosphere and is connected to the solar envelope, allowing the huge abundance variations to occur, which might otherwise be problematic with a coronal fractionation site. The principal mechanism behind the mass-independent FIP fractionation becoming the mass-dependent impulsive SEP fractionation is the suppression of acoustic waves in the chromosphere. The ponderomotive force causing the fractionation must be due to torsional Alfvén waves, which couple much less effectively to slow modes than do shear waves, and upward-propagating acoustic waves deriving from photospheric convection must be effectively mode-converted to fast modes at the chromospheric layer, where Alfvén and sound speeds are equal, and subsequently totally internally reflected. We further discuss observations of the environments thought to be the source of impulsive SEPs and the extent to which the real Sun might meet these conditions.

Published

2023

2. Evolution of Flare-Accelerated Electrons Quantified by Spatially Resolved Analysis

Author

Natsuha Kuroda, Gregory D. Fleishman, Dale E. Gary, Gelu M. Nita, Bin Chen, and Sijie Yu

Subjects

solar flares, microwave, imaging spectroscopy, non-thermal electrons, numerical modeling, X-ray, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

Non–thermal electrons accelerated in solar flares produce electromagnetic emission in two distinct, highly complementary domains—hard X-rays (HXRs) and microwaves (MWs). This paper reports MW imaging spectroscopy observations from the Expanded Owens Valley Solar Array of an M1.2 flare that occurred on 2017 September 9, from which we deduce evolving coronal parameter maps. We analyze these data jointly with the complementary Reuven Ramaty High-Energy Solar Spectroscopic Imager HXR data to reveal the spatially-resolved evolution of the non-thermal electrons in the flaring volume. We find that the high-energy portion of the non-thermal electron distribution, responsible for the MW emission, displays a much more prominent evolution (in the form of strong spectral hardening) than the low-energy portion, responsible for the HXR emission. We show that the revealed trends are consistent with a single electron population evolving according to a simplified trap-plus-precipitation model with sustained injection/acceleration of non-thermal electrons, which produces a double-powerlaw with steadily increasing break energy.

Published

2020

3. Frequency Agile Solar Radiotelescope

Author

Dale E. Gary, Bin Chen, James F. Drake, Gregory D. Fleishman, Lindsay Glesener, Pascal Saint-Hilaire, Stephen M. White, Timothy Bastian, Sijie Yu, Surajit Mondal, Angelos Vourlidas, Stuart D. Bale, Sherry Chhabra, Christina M. S. Cohen, Craig DeForest, Juan Carlos Martinez Oliveros, Hantao Ji, Juan Camilo Buitrago-Casas, Shadia Habbal, Louis J. Lanzerotti, Shaheda Begum Shaik, Momchil Molnar, Gelu Nita, Gordon Emslie, Kevin Reardon, Fan Guo, Mitsuo Oka, Nariaki Nitta, Xudong Sun, Enrico Landi, Leon Ofman, Jeongwoo Lee, Hugh Hudson, Astrid Veronig, Jiong Qiu, KD Leka, John Harvey, Thomas Y. Chen, Spiro Kosta Antiochos, Ronald L Moore, Matthew West, Joel Timothy Dahlin, Alexander Georgievich Kosovichev, Delores Knipp, Xiaocan Li, Thomas Schad, Eduard Kontar, Laura Hayes, Vasyl Yurchyshyn, Chun Ming Mark Cheung, Valentin Martinez Pillet, Lucas Tarr, Judith Tobi Karpen, Amir Caspi, Albert Young-ming Shih, Tetsu Anan, Andrea Francesco Battaglia, Haosheng Lin, Meriem Alaoui Abdallaoui, Katharine K Reeves, Silvina E Guidoni, James Andrew Klimchuk, Jason Kooi, Maria Dmitriyevna Kazachenko, Samuel Tun Beltran, James McTiernan, Natsuha Kuroda, Samuel Schonfeld, Stephen Kahler, Cooper J Downs, Gianna Cauzzi, Sophie Musset, Chris R. Gilly, Ayumi Asai, Brian Welsch, Masumi Shimojo, Yuhong Fan, Satoshi Masuda, Brian ODonnell, Pankaj Kumar, and Jeffrey W Brosius

Subjects

Instrumentation And Photography, Solar Physics, Space Sciences (General)

Abstract

The Frequency Agile Solar Radiotelescope (FASR) has been strongly endorsed as a top community priority by both Astronomy & Astrophysics Decadal Surveys and Solar & Space Physics Decadal Surveys in the past two decades. Although it was developed to a high state of readiness in previous years (it went through a CATE analysis and was declared “doable now”), the NSF has not had the funding mechanisms in place to fund this mid-scale program. Now it does, and the community must seize this opportunity to modernize the FASR design and build the instrument in this decade. The concept and its science potential have been abundantly proven by the pathfinding Expanded Owens Valley Solar Array (EOVSA), which has demonstrated a small subset of FASR’s key capabilities such as dynamically measuring the evolving magnetic field in eruptive flares, the temporal and spatial evolution of the electron energy distribution in flares, and the extensive coupling among dynamic components (flare, flux rope, current sheet). The FASR concept, which is orders of magnitude more powerful than EOVSA, is low-risk and extremely high reward, exploiting a fundamentally new research domain in solar and space weather physics. Utilizing dynamic broadband imaging spectropolarimetry at radio wavelengths, with its unique sensitivity to coronal magnetic fields and to both thermal plasma and nonthermal electrons from large flares to extremely weak transients, the ground-based FASR will make synoptic measurements of the coronal magnetic field and map emissions from the chromosphere to the middle corona in 3D. With its high spatial, spectral, and temporal resolution, as well as its superior imaging fidelity and dynamic range, FASR is poised to provide a system-wide perspective on myriad coupled phenomena. FASR will be a highly complementary and synergistic component of solar and heliospheric observing capabilities that is critically needed to support the next generation of solar science.

Published

2022

4. Machine Learning in Heliophysics and Space Weather Forecasting: A White Paper of Findings and Recommendations.

Author

Gelu Nita, Manolis K. Georgoulis, Irina Kitiashvili, Viacheslav Sadykov, Enrico Camporeale, Alexander Kosovichev, Haimin Wang, Vincent Oria, Jason T. L. Wang, Rafal A. Angryk, Berkay Aydin, Azim Ahmadzadeh, Xiaoli Bai, Timothy Bastian, Soukaina Filali Boubrahimi, Bin Chen, Alisdair Davey, Sheldon Fereira, Gregory Fleishman, Dale Gary, Andrew Gerrard, Gregory Hellbourg, Katherine Herbert, Jack Ireland, Egor Illarionov, Natsuha Kuroda, Qin Li, Chang Liu, Yuexin Liu, Hyomin Kim, Dustin Kempton, Ruizhe Ma, Petrus C. Martens, Ryan M. McGranaghan, Edward Semones, John T. Stefan, Andrey Stejko, Yaireska Collado-Vega, Meiqi Wang, Yan Xu, and Sijie Yu

Published

2020

5. Machine Learning in Heliophysics and space weather forecasting: a white paper of finding and recommendations

Author

Irina Nikolaevna Kitiashvili, Gelu Nita, Manolis Georgoulis, Irina Kitiashvili, Viacheslav Sadykov, Enrico Camporeale, Alexander Kosovichev, Haimin Wang, Vincent Oria, Jason Wang, Rafal Angryk, Berkay Aydin, Azim Ahmadsadeh, Xiaoli Bai, Timothy Bastian, Soukaina Filali Boubrahimi, Bin Chen, Alisdair Davey, Sheldon Fereira, Gregory Fleishman, Dale Gary, Andrew Gerrard, Gregory Hellbourg, Katherine Herbert, Jack Ireland, Egor Illarionov, Natsuha Kuroda, Qin Li, Chang Liu, Yuexin Liu, Hyomin Kim, Dustin Kempton, Ruizhe Ma, Petrus Martens, Ryan Mcgranaghan, Edward Semones, John Stefan, Andrey Stejko, Yaireska Collado Vega, Meiqi Weng, Yang Xu, and Sijie Yu

Subjects

Aeronautics (General)

Abstract

The authors of this white paper met on 16-17 January 2020 at the New Jersey Institute of Technology,Newark, NJ, for a 2-day workshop that brought together a group of heliophysicists, data providers,expert modelers, and computer/data scientists. Their objective was to discuss critical developments and prospects of the application of machine and/or deep learning techniques for data analysis, modeling and forecasting in Heliophysics, and to shape a strategy for further developments in the field. The workshop combined a set of plenary sessions featuring invited introductory talks interleaved with a set of open discussion sessions. The outcome of the discussion is encapsulated in this white paper that also features a top-level list of recommendations agreed by participants

Published

2020

6. Element Abundances: A New Diagnostic for the Solar Wind

Author

J. Martin Laming, Angelos Vourlidas, Clarence Korendyke, Damien Chua, Steven R. Cranmer, Yuan-Kuen Ko, Natsuha Kuroda, Elena Provornikova, John C. Raymond, Nour-Eddine Raouafi, Leonard Strachan, Samuel Tun-Beltran, Micah Weberg, and Brian E. Wood

Published

2019

7. In-flight Calibration and Data Reduction for the WISPR Instrument On Board the PSP Mission

Author

Phillip Hess, Dennis Wang, N. Rich, Karl Battams, Robin C. Colaninno, Mark G. Linton, Angelos Vourlidas, Natsuha Kuroda, Russell A. Howard, A. Thernisien, and Guillermo Stenborg

Subjects

Physics, Brightness, Vignetting, 010504 meteorology & atmospheric sciences, Instrumentation, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Linearity, Astronomy and Astrophysics, Image processing, 01 natural sciences, Space and Planetary Science, Physics::Space Physics, 0103 physical sciences, Calibration, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Data reduction, Remote sensing

Abstract

We present the calibration status and data reduction methodology for the Wide Field Imager for Solar Probe (WISPR) on board the Parker Solar Probe (PSP) mission. In particular, we describe the process for converting a raw image, measured in digital numbers (DN), to a calibrated image, measured in mean solar brightness (MSB). We also discuss details of the on board image processing including bias removal, the linearity of the electronics, pointing, geometric distortion, and photometric calibration using stellar measurements, and the characterization of vignetting and other instrumental artifacts. The analysis presented here is based on data from the first four WISPR orbits. As the PSP perihelia get progressively closer to the Sun and the WISPR concept of operation evolves to deal with the brighter scene, the calibration will likely need to be updated. Aging of the optics and the possibility of detector degradation may also occur. Hence, we consider the WISPR calibration as work in progress with updates reported as necessary.

Published

2021

8. Evolution of Flare-Accelerated Electrons Quantified by Spatially Resolved Analysis

Author

Bin Chen, Dale E. Gary, Gregory D. Fleishman, Natsuha Kuroda, Gelu M. Nita, and Sijie Yu

Subjects

solar flares, microwave, lcsh:Astronomy, Astrophysics::High Energy Astrophysical Phenomena, Population, FOS: Physical sciences, Astrophysics, Electron, imaging spectroscopy, non-thermal electrons, 01 natural sciences, law.invention, X-ray, lcsh:QB1-991, law, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, education, 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), Physics, education.field_of_study, Solar flare, 010308 nuclear & particles physics, Spatially resolved, lcsh:QC801-809, Astronomy and Astrophysics, lcsh:Geophysics. Cosmic physics, Imaging spectroscopy, numerical modeling, Astrophysics - Solar and Stellar Astrophysics, Physics::Space Physics, Owens Valley Solar Array, Microwave, Flare

Abstract

Nonthermal electrons accelerated in solar flares produce electromagnetic emission in two distinct, highly complementary domains - hard X-rays (HXRs) and microwaves (MWs). This paper reports MW imaging spectroscopy observations from the Expanded Owens Valley Solar Array of an M1.2 flare that occurred on 2017 September 9, from which we deduce evolving coronal parameter maps. We analyze these data jointly with the complementary Reuven Ramaty High-Energy Solar Spectroscopic Imager HXR data to reveal the spatially-resolved evolution of the nonthermal electrons in the flaring volume. We find that the high-energy portion of the nonthermal electron distribution, responsible for the MW emission, displays a much more prominent evolution (in the form of strong spectral hardening) than the low-energy portion, responsible for the HXR emission. We show that the revealed trends are consistent with a single electron population evolving according to a simplified trap-plus-precipitation model with sustained injection/acceleration of nonthermal electrons, which produces a double-powerlaw with steadily increasing break energy., 28 pages, 10 figures, accepted in Frontiers in Astronomy and Space Sciences, section Stellar and Solar Physics

Published

2020

9. Evolution of Flare-accelerated Electrons in the Solar Corona and Chromosphere Revealed by Spatially Resolved Microwave and Hard X-Ray Analysis

Author

Gelu M. Nita, Sijie Yu, Bin Chen, Natsuha Kuroda, Gregory D. Fleishman, and Dale E. Gary

Subjects

Physics, law, Spatially resolved, Astrophysics, Electron, X ray analysis, Chromosphere, Microwave, Flare, law.invention

Abstract

Hard X-ray (HXR) and microwave (MW) observations are highly complementary for studying electron acceleration and transport processes in solar flares. In recent years, a new effort has been made in the MW domain using new high-resolution, multifrequency data from The Expanded Owens Valley Solar Array (EOVSA) and a breakthrough numerical modeling infrastructure that enables us to study properties of high-energy electrons in unprecedented cadence and quantitative detail. This study introduces the observation of an M1.2 flare that occurred on 2017 September 9 and analyzes the evolution of the nonthermal electrons in the corona based on EOVSA MW spectral imaging data. We find a significant spectral hardening of the MWemitting nonthermal electron population in the corona, using EOVSA lower-frequency (

Published

2020

10. Characterization of turbulent magnetic reconnection in solar flares with microwave imaging spectroscopy

Author

Gregory D. Fleishman, Gelu M. Nita, Sijie Yu, Natsuha Kuroda, Bin Chen, and Dale E. Gary

Subjects

Microwave imaging, Materials science, Solar flare, Turbulence, Astrophysics::High Energy Astrophysical Phenomena, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Magnetic reconnection, Astrophysics, Spectroscopy, Characterization (materials science)

Abstract

Magnetic reconnection plays a central role in highly magnetized plasma, for example, in solar corona. Release of magnetic energy due to reconnection is believed to drive such transient phenomena as solar flares, eruptions, and jets. This energy release should be associated with a decrease of the coronal magnetic field. Quantitative measurements of the evolving magnetic field strength in the corona are required to find out where exactly and with what rate this decrease takes place. The only available methodology capable of providing such measurements employs microwave imaging spectroscopy of gyrosynchrotron emission from nonthermal electrons accelerated in flares. Here, we report microwave observations of a solar flare, showing spatial and temporal changes in the coronal magnetic field at the cusp region; well below the nominal reconnection X point. The field decays at a rate of ~5 Gauss per second for 2 minutes. This fast rate of decay implies a highly enhanced, turbulent magnetic diffusivity and sufficiently strong electric field to account for the particle acceleration that produces the microwave emission. Moreover, spatially resolved maps of the nonthermal and thermal electron densities derived from the same microwave spectroscopy data set allow us to detect the very acceleration site located within the cusp region. The nonthermal number density is extremely high, while the thermal one is undetectably low in this region indicative of a bulk acceleration process exactly where the magnetic field displays the fast decay. The decrease in stored magnetic energy is sufficient to power the solar flare, including the associated eruption, particle acceleration, and plasma heating. We discuss implications of these findings for understanding particle acceleration in solar flares and in a broader space plasma context.

Published

2020

11. Revealing evolution of nonthermal electrons in solar flares using 3D modeling

Author

Kevin Tong, Gregory D. Fleishman, Gelu M. Nita, Zhou Zhizhuo, Natsuha Kuroda, Sabina Jia, and Richard R. Wen

Subjects

Physics, 010504 meteorology & atmospheric sciences, Solar flare, Turbulence, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, Astronomy and Astrophysics, Electron, Astrophysics, 01 natural sciences, law.invention, Particle acceleration, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, law, 0103 physical sciences, Thermal, Physics::Space Physics, Particle, Astrophysics::Solar and Stellar Astrophysics, Diffusion (business), 010303 astronomy & astrophysics, Solar and Stellar Astrophysics (astro-ph.SR), 0105 earth and related environmental sciences, Flare

Abstract

Understanding nonthermal particle generation, transport, and escape in solar flares requires detailed quantification of the particle evolution in the realistic 3D domain where the flare takes place. Rather surprisingly, apart of standard flare scenario and integral characteristics of the nonthermal electrons, not much is known about actual evolution of nonthermal electrons in the 3D spatial domain. This paper attempts to begin to remedy this situation by creating sets of evolving 3D models, the synthesized emission from which matches the evolving observed emission. Here we investigate two contrasting flares: a dense, "coronal-thick-target" flare SOL2002-04-12T17:42, that contained a single flare loop observed in both microwave and X-ray, and a more complex flare, SOL2015-06-22T17:50, that contained at least four distinct flaring loops needed to consistently reproduce the microwave and X-ray emission. Our analysis reveals differing evolution pattern of the nonthermal electrons in the dense and tenuous loops; however, both of which imply the central role of resonant wave-particle interaction with turbulence. These results offer new constraints for theory and models of the particle acceleration and transport in solar flares., Comment: ApJ accepted; 12 pages, 13 figures

Published

2018

12. Three-dimensional Forward-fit Modeling of the Hard X-Ray and the Microwave Emissions of the 2015 June 22 M6.5 Flare

Author

Dale E. Gary, Ju Jing, Haimin Wang, Gregory D. Fleishman, Gelu M. Nita, and Natsuha Kuroda

Subjects

Physics, 010504 meteorology & atmospheric sciences, Solar flare, Astrophysics::High Energy Astrophysical Phenomena, Gamma ray, X-ray, FOS: Physical sciences, Astronomy and Astrophysics, Astrophysics, 7. Clean energy, 01 natural sciences, law.invention, Astrophysics - Solar and Stellar Astrophysics, Space and Planetary Science, law, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics, Microwave, Solar and Stellar Astrophysics (astro-ph.SR), 0105 earth and related environmental sciences, Flare

Abstract

The well-established notion of a "common population" of the accelerated electrons simultaneously producing the hard X-ray (HXR) and the microwave (MW) emission during the flare impulsive phase has been challenged by some studies reporting the discrepancies between the HXR-inferred and the MW-inferred electron energy spectra. The traditional methods of their spectral inversion have some problems that can be mainly attributed to the unrealistic and the oversimplified treatment of the flare emission. To properly address this problem, we use a Non-linear Force Free Field (NLFFF) model extrapolated from an observed photospheric magnetogram as input to the three-dimensional, multi-wavelength modeling platform GX Simulator, and create a unified electron population model that can simultaneously reproduce the observed HXR and MW observations. We model the end of the impulsive phase of the 2015-06-22 M6.5 flare, and constrain the modeled electron spatial and energy parameters using observations made by the highest-resolving instruments currently available in two wavelengths, the Reuven Ramaty High Energy Solar Spectroscopic Imager (RHESSI) for HXR and the Expanded Owens Valley Solar Array (EOVSA) for MW. Our results suggest that the HXR-emitting electron population model fits the standard flare model with a broken power-law spectrum (E_break ~ 200 keV) that simultaneously produces the HXR footpoint emission and the MW high frequency emission. The model also includes an "HXR invisible" population of nonthermal electrons that are trapped in a large volume of magnetic field above the HXR-emitting loops, which is observable by its gyrosynchrotron (GS) radiation emitting mainly in MW low frequency range.

Published

2017

13. OBSERVATION OF THE 2011-02-15 X2.2 FLARE IN THE HARD X-RAY AND MICROWAVE

Author

Dale E. Gary, Natsuha Kuroda, and Haimin Wang

Subjects

Physics, Solar flare, Gamma ray, Astronomy and Astrophysics, Magnetic reconnection, Astrophysics, Electron, Light curve, Polarization (waves), law.invention, Space and Planetary Science, law, Microwave, Flare

Abstract

Previous studies have shown that the energy release mechanism of some solar flares follow the Standard magnetic-reconnection model, but the detailed properties of high-energy electrons produced in the flare are still not well understood. We conducted a unique, multi-wavelength study that discloses the spatial, temporal and energy distributions of the accelerated electrons in the X2.2 solar flare on 2011 February 15. We studied the source locations of seven distinct temporal peaks observed in hard X-ray (HXR) and microwave (MW) light curves using the RHESSI in 50–75 keV channels and Nobeyama Radioheliograph in 34 GHz, respectively. We found that the seven emission peaks did not come from seven spatially distinct sites in HXR and MW, but rather in HXR we observed a sudden change in location only between the second and the third peak, with the same pattern occurring, but evolving more slowly in MW. Comparison between the HXR light curve and the temporal variations in intensity in the two MW source kernels also confirmed that the seven peaks came predominantly from two sources, each with multiple temporal peaks. In addition, we studied the polarization properties of MW sources, and time delay between HXR and MW. We discuss our results in the context of the tether-cutting model.

Published

2015

14. Revealing the Evolution of Non-thermal Electrons in Solar Flares Using 3D Modeling.

Author

Gregory D. Fleishman, Gelu M. Nita, Natsuha Kuroda, Sabina Jia, Kevin Tong, Richard R. Wen, and Zhou Zhizhuo

Subjects

ELECTRONS, SOLAR flares, ATOMS, SOLAR activity, NANOPARTICLES

Abstract

Understanding non-thermal particle generation, transport, and escape in solar flares requires detailed quantification of the particle evolution in the realistic 3D domain where the flare takes place. Rather surprisingly, apart from the standard flare scenario and integral characteristics of non-thermal electrons, not much is known about the actual evolution of non-thermal electrons in the 3D spatial domain. This paper attempts to begin to remedy this situation by creating sets of evolving 3D models, the synthesized emission from which matches the evolving observed emission. Here, we investigate two contrasting flares: a dense, “coronal-thick-target” flare SOL2002-04-12T17:42, that contained a single flare loop observed in both microwaves and X-rays, and a more complex flare, SOL2015-06-22T17:50, that contained at least four distinct flaring loops needed to consistently reproduce the microwave and X-ray emission. Our analysis reveals differing evolution patterns for the non-thermal electrons in the dense and tenuous loops; however, both patterns suggest that resonant wave–particle interactions with turbulence play a central role. These results offer new constraints for theory and models of the particle acceleration and transport in solar flares. [ABSTRACT FROM AUTHOR]

Published

2018

15. Three-dimensional Forward-fit Modeling of the Hard X-Ray and Microwave Emissions of the 2015 June 22 M6.5 Flare.

Author

Natsuha Kuroda, Dale E. Gary, Haimin Wang, Gregory D. Fleishman, Gelu M. Nita, and Ju Jing

Subjects

*ELECTRON energy states, *HARD X-rays, *SOLAR granulation, *SYNCHROTRON radiation, *MAGNETIC fields, *HIGH energy astronomy observatories

Abstract

The well-established notion of a “common population” of the accelerated electrons simultaneously producing the hard X-ray (HXR) and microwave (MW) emission during the flare impulsive phase has been challenged by some studies reporting the discrepancies between the HXR-inferred and MW-inferred electron energy spectra. The traditional methods of spectral inversion have some problems that can be mainly attributed to the unrealistic and oversimplified treatment of the flare emission. To properly address this problem, we use a nonlinear force-free field (NLFFF) model extrapolated from an observed photospheric magnetogram as input to the three-dimensional, multiwavelength modeling platform GX Simulator and create a unified electron population model that can simultaneously reproduce the observed HXR and MW observations. We model the end of the impulsive phase of the 2015 June 22 M6.5 flare and constrain the modeled electron spatial and energy parameters using observations made by the highest-resolving instruments currently available in two wavelengths, the Reuven Ramaty High Energy Solar Spectroscopic Imager for HXR and the Expanded Owens Valley Solar Array for MW. Our results suggest that the HXR-emitting electron population model fits the standard flare model with a broken power-law spectrum ( keV) that simultaneously produces the HXR footpoint emission and the MW high-frequency emission. The model also includes an “HXR-invisible” population of nonthermal electrons that are trapped in a large volume of magnetic field above the HXR-emitting loops, which is observable by its gyrosynchrotron radiation emitting mainly in the MW low-frequency range. [ABSTRACT FROM AUTHOR]

Published

2018

16. OBSERVATION OF THE 2011-02-15 X2.2 FLARE IN THE HARD X-RAY AND MICROWAVE.

Author

Natsuha Kuroda, Haimin Wang, and Dale E. Gary

Subjects

*SOLAR flares, *MAGNETIC reconnection, *LIGHT curves, *SOLAR radio emission, *GAMMA rays

Abstract

Previous studies have shown that the energy release mechanism of some solar flares follow the Standard magnetic-reconnection model, but the detailed properties of high-energy electrons produced in the flare are still not well understood. We conducted a unique, multi-wavelength study that discloses the spatial, temporal and energy distributions of the accelerated electrons in the X2.2 solar flare on 2011 February 15. We studied the source locations of seven distinct temporal peaks observed in hard X-ray (HXR) and microwave (MW) light curves using the RHESSI in 50–75 keV channels and Nobeyama Radioheliograph in 34 GHz, respectively. We found that the seven emission peaks did not come from seven spatially distinct sites in HXR and MW, but rather in HXR we observed a sudden change in location only between the second and the third peak, with the same pattern occurring, but evolving more slowly in MW. Comparison between the HXR light curve and the temporal variations in intensity in the two MW source kernels also confirmed that the seven peaks came predominantly from two sources, each with multiple temporal peaks. In addition, we studied the polarization properties of MW sources, and time delay between HXR and MW. We discuss our results in the context of the tether-cutting model. [ABSTRACT FROM AUTHOR]

Published

2015