Unraveling the Thermodynamic Enigma between Fast and Slow Coronal Mass Ejections

Khuntia, Soumyaranjan; Mishra, Wageesh; Mishra, Sudheer K.; Wang, Yuming; Zhang, Jie; Lyu, Shaoyu

doi:10.3847/1538-4357/ad00ba

ApJ

2023

DOI: 10.3847/1538-4357/ad00ba

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Unraveling the Thermodynamic Enigma between Fast and Slow Coronal Mass Ejections

Soumyaranjan Khuntia,

Wageesh Mishra,

Sudheer K. Mishra

et al.

Abstract: Coronal mass ejections (CMEs) are the most energetic expulsions of magnetized plasma from the Sun that play a crucial role in space weather dynamics. This study investigates the diverse kinematics and thermodynamic evolution of two CMEs (CME1: 2011 September 24 and CME2: 2018 August 20) at coronal heights where thermodynamic measurements are limited. The peak 3D propagation speed of CME1 is high (1885 km s−1) with two-phase expansion (rapid and nearly constant), while the peak 3D propagation speed of CME2 is s… Show more

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Cited by 3 publications

References 91 publications

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Comprehensive Characterization of the Dynamics of Two Coronal Mass Ejections in the Outer Corona

Di Lorenzo,

Balmaceda,

Cremades

et al. 2024

Sol Phys

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Comprehensive Characterization of the Dynamics of Two Coronal Mass Ejections in the Outer Corona

Di Lorenzo,

Balmaceda,

Cremades

et al. 2024

Sol Phys

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Non-conventional approach for deriving the radial sizes of coronal mass ejections at different instances: discrepancies in the estimates between remote and in situ observations

Agarwal,

Mishra

2024

Monthly Notices of the Royal Astronomical Society

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Understanding the evolution of radial sizes and instantaneous expansion speeds of coronal mass ejections (CMEs) is crucial for assessing their impact duration on Earth’s environment. We introduce a non-conventional approach to derive the CME’s radial sizes and expansion speeds at different instances during its passage over a single-point in situ spacecraft. We also estimate the CME’s radial sizes and expansion speeds during its journey from the Sun to 1 AU using the 3D kinematics of different CME features, including the leading edge (LE), center, and trailing edge (TE). The continuous 3D kinematics of the CME is estimated by employing the GCS and SSSE reconstruction methods on multi-point observations from coronagraphs and heliospheric imagers combined with the drag-based model. We choose the 2010 April 3 CME as a suitable case for our study, promising a more accurate comparison of its remote and in situ observations. We show that the introduced non-conventional approach can provide better accuracy in estimating radial sizes and instantaneous expansion speeds of CMEs at different instances. We examine the aspect ratio of the CME, which influences its expansion behavior and shows the discrepancy between its value in the corona and interplanetary medium. Our study highlights significant inconsistencies in the arrival time, radial size, and expansion speed estimates obtained from remote and in situ observations. We advocate for future studies leveraging multi-spacecraft in situ observations and our non-conventional approach to analyze them to improve the comprehension of CME dynamics in the solar wind.

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Deciphering the evolution of thermodynamic properties and their connection to the global kinematics of high-speed coronal mass ejections using FRIS model

Khuntia,

Mishra,

Wang

et al. 2024

Monthly Notices of the Royal Astronomical Society

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Most earlier studies have been limited to estimating the kinematic evolution of coronal mass ejections (CMEs), and only limited efforts have been made to investigate their thermodynamic evolution. We focus on the interplay of the thermal properties of CMEs with their observed global kinematics. We implement the Flux rope Internal State (FRIS) model to estimate variations in the polytropic index, heating rate per unit mass, temperature, pressure, and various internal forces. The model incorporates inputs of 3D kinematics obtained from the Graduated Cylindrical Shell (GCS) model. In our study, we chose nine fast-speed CMEs from 2010 to 2012. Our investigation elucidates that the selected fast-speed CMEs show a heat-release phase at the beginning, followed by a heat-absorption phase with a near-isothermal state in their later propagation phase. The thermal state transition, from heat release to heat absorption, occurs at around 3(±0.3) to 7(±0.7) R⊙ for different CMEs. We found that the CMEs with higher expansion speeds experience a less pronounced sharp temperature decrease before gaining a near-isothermal state. The differential emission measurement (DEM) analysis findings, using multi-wavelength observation from SDO/AIA, also show a heat release state of CMEs at lower coronal heights. We also find the dominant internal forces influencing CME radial expansion at varying distances from the Sun. Our study shows the need to characterize the internal thermodynamic properties of CMEs better in both observational and modeling studies, offering insights for refining assumptions of a constant value of the polytropic index during the evolution of CMEs.

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Unraveling the Thermodynamic Enigma between Fast and Slow Coronal Mass Ejections

Cited by 3 publications

References 91 publications

Comprehensive Characterization of the Dynamics of Two Coronal Mass Ejections in the Outer Corona

Comprehensive Characterization of the Dynamics of Two Coronal Mass Ejections in the Outer Corona

Non-conventional approach for deriving the radial sizes of coronal mass ejections at different instances: discrepancies in the estimates between remote and in situ observations

Deciphering the evolution of thermodynamic properties and their connection to the global kinematics of high-speed coronal mass ejections using FRIS model

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