Solar activity and space weather

Gopalswamy, Ν.; Mäkelä, P.; Yashiro, S.; Akiyama, S.; Xie, H.

doi:10.1088/1742-6596/2214/1/012021

Cited by 10 publications

(8 citation statements)

References 43 publications

(57 reference statements)

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“…Toward the end of this cycle, an intense storm has been observed on 26 August 2018 with a Dst index of −175 nT. Only two storms in solar cycle 24 are stronger than this event: The 17 March 2015 (−222 nT) and 23 June 2015 (−204 nT) storms (see e.g., Gopalswamy, Akiyama, et al., 2015; Liu et al., 2015; Webb & Nitta, 2017; Wu et al., 2016). The 26 August 2018 event is characterized by weak solar eruption, significant flux rope rotation in the corona and interplanetary (IP) medium, and an intense geomagnetic storm, as first reported by Chen et al.…”

Section: Introductionmentioning

confidence: 96%

What Is Unusual About the Third Largest Geomagnetic Storm of Solar Cycle 24?

et al. 2022

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We report on the solar and interplanetary (IP) causes of the third largest geomagnetic storm (26 August 2018) in solar cycle 24. The underlying coronal mass ejection (CME) originating from a quiescent filament region becomes a 440 km/s magnetic cloud (MC) at 1 au after ∼5 days. The prolonged CME acceleration (for ∼24 hr) coincides with the time profiles of the post‐eruption arcade intensity and reconnected flux. Chen et al. (2019, https://doi.org/10.3847/1538-4357/ab3f36) obtain a lower speed since they assumed that the CME does not accelerate after ∼12 hr. The presence of multiple coronal holes near the filament channel and the high‐speed wind from them seem to have the combined effect of producing complex rotation in the corona and IP medium resulting in a high‐inclination MC. The Dst time profile in the main phase steepens significantly (rapid increase in storm intensity) coincident with the density increase (prominence material) in the second half of the MC. Simulations using the Comprehensive Inner Magnetosphere‐Ionosphere model show that a higher ring current energy results from larger dynamic pressure (density) in MCs. Furthermore, the Dst index is highly correlated with the main‐phase time integral of the ring current injection that includes density, consistent with the simulations. A complex temporal structure develops in the storm main phase if the underlying MC has a complex density structure during intervals of southward IP magnetic field. We conclude that the high intensity of the storm results from the prolonged CME acceleration, complex rotation of the CME flux rope, and the high density in the 1‐au MC.

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Section: Introductionmentioning

confidence: 96%

What Is Unusual About the Third Largest Geomagnetic Storm of Solar Cycle 24?

et al. 2022

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“…Most models have been developed and validated on events that occurred during specific phases of a specific solar cycle, with the bulk of the model validation and parameters testing work done during cycle 23. It is well known that substantial differences in the physical properties of the solar wind populating the heliosphere during different solar cycles may exist (see e.g., Gopalswamy, 2006; Gopalswamy et al., 2022; Gopalswamy, Xie, et al., 2015; Gopalswamy, Yashiro, et al., 2015; Michalek et al., 2022, and references therein). Therefore, permanent assessment of the solar cycle variations, regarding in particular the background solar wind, needs to become an integral part of the forecast operations.…”

Section: Discussionmentioning

confidence: 99%

Refined Modeling of Geoeffective Fast Halo CMEs During Solar Cycle 24

Yordanova,

Temmer,

Dumbović

et al. 2024

Space Weather

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The propagation of geoeffective fast halo coronal mass ejections (CMEs) from solar cycle 24 has been investigated using the European Heliospheric Forecasting Information Asset (EUHFORIA), ENLIL, Drag‐Based Model (DBM) and Effective Acceleration Model (EAM) models. For an objective comparison, a unified set of a small sample of CME events with similar characteristics has been selected. The same CME kinematic parameters have been used as input in the propagation models to compare their predicted arrival times and the speed of the interplanetary (IP) shocks associated with the CMEs. The performance assessment has been based on the application of an identical set of metrics. First, the modeling of the events has been done with default input concerning the background solar wind, as would be used in operations. The obtained CME arrival forecast deviates from the observations at L1, with a general underestimation of the arrival time and overestimation of the impact speed (mean absolute error [MAE]: 9.8 ± 1.8–14.6 ± 2.3 hr and 178 ± 22–376 ± 54 km/s). To address this discrepancy, we refine the models by simple changes of the density ratio (dcld) between the CME and IP space in the numerical, and the IP drag (γ) in the analytical models. This approach resulted in a reduced MAE in the forecast for the arrival time of 8.6 ± 2.2–13.5 ± 2.2 hr and the impact speed of 51 ± 6–243 ± 45 km/s. In addition, we performed multi‐CME runs to simulate potential interactions. This leads, to even larger uncertainties in the forecast. Based on this study we suggest simple adjustments in the operational settings for improving the forecast of fast halo CMEs.

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“…Recent investigations have shown that the space weather due to CIRs are milder in SC 24 [114,[143][144][145][146]. Gopalswamy et al [144] reported that the number of intense geomagnetic storms caused by CIRs has dropped by 75% in SC 24. Grandin et al [146] report that stream SIR/HSSs are 20-40% less geoeffective during cycle 24 than during SC23.…”

Section: Coronal Holes and Geomagnetic Stormsmentioning

confidence: 99%

“…The severest reduction is in the number of GLEs: 16 in SC 23 vs. just 2 in SC 24 (i.e., an 87% drop). This has been attributed to the reduced acceleration efficiency in the weakened ambient magnetic field, so particles did not attain high energies [55,144]. An additional reason could be the presence of fewer seed particles [188].…”

Section: Solar Cycle Dependence Of Space Weather Consequencesmentioning

confidence: 99%

The Sun and Space Weather

Gopalswamy

2022

Atmosphere

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The explosion of space weather research since the early 1990s has been partly fueled by the unprecedented, uniform, and extended observations of solar disturbances from space- and ground-based instruments. Coronal mass ejections (CMEs) from closed magnetic field regions and high-speed streams (HSS) from open-field regions on the Sun account for most of the disturbances relevant to space weather. The main consequences of CMEs and HSS are their ability to cause geomagnetic storms and accelerate particles. Particles accelerated by CME-driven shocks can pose danger to humans and their technological structures in space. Geomagnetic storms produced by CMEs and HSS-related stream interaction regions also result in particle energization inside the magnetosphere that can have severe impact on satellites operating in the magnetosphere. Solar flares are another aspect of solar magnetic energy release, mostly characterized by the sudden enhancement in electromagnetic emission at various wavelengths—from radio waves to gamma-rays. Flares are responsible for the sudden ionospheric disturbances and prompt perturbation of Earth’s magnetic field known as magnetic crochet. Nonthermal electrons accelerated during flares can emit intense microwave radiation that can drown spacecraft and radar signals. This review article summarizes major milestones in understanding the connection between solar variability and space weather.

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Solar activity and space weather

Cited by 10 publications

References 43 publications

What Is Unusual About the Third Largest Geomagnetic Storm of Solar Cycle 24?

What Is Unusual About the Third Largest Geomagnetic Storm of Solar Cycle 24?

Refined Modeling of Geoeffective Fast Halo CMEs During Solar Cycle 24

The Sun and Space Weather

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