A Signature of 27 day Solar Rotation in the Concentration of Metallic Ions within the Terrestrial Ionosphere

Yu, Bingkun; Scott, Christopher J.; Xue, Xianghui; Yue, Xinan; Chi, Yutian; Dou, Xiankang; Lockwood, Mike

doi:10.3847/1538-4357/ac0886

Cited by 13 publications

(14 citation statements)

References 85 publications

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“…The model overestimated small S4max values and underestimated large S4max values. This is because, in this study, the model provides a climatology of E s layers, while other electrodynamic processes, for example, the neutral wind shear effect on the vertical motion of ions (Yu et al, 2019) and the geomagnetic activity effect on the significant periodic oscillations in E s layers (Yu, Scott, Xue, Yue, Chi, et al, 2021) satellite RO measurements, although the prediction of E s layers is severely constrained at present due to a lack of sufficient thermospheric wind data. Figure 10 shows the global distributions of the intensity of E s layers at 0 UT in the four seasons, represented by S4max from satellite RO observations and the model outputs in the period 2006-2014.…”

Section: Model Resultsmentioning

confidence: 99%

“…The short-term variations in the low-and high-latitude E s layers are associated with fast solar wind streams (Davies, 1990;L. Resende et al, 2021) and recurrent geomagnetic activity (Yu, Scott, Xue, Yue, Chi, et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…Besides, the influences of solar activity, equatorial electrojet current plasma instabilities, and geomagnetic disturbances are not yet included in the model. The short‐term variations in the low‐ and high‐latitude E s layers are associated with fast solar wind streams (Davies, 1990; L. Resende et al., 2021) and recurrent geomagnetic activity (Yu, Scott, Xue, Yue, Chi, et al., 2021).…”

Section: Discussionmentioning

confidence: 99%

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An Empirical Model of the Ionospheric Sporadic E Layer Based on GNSS Radio Occultation Data

Xue

Scott

et al. 2022

Space Weather

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The intense plasma irregularities within the ionospheric sporadic E (Es) layers at 90–130 km altitude have a significant impact on radio communications and navigation systems. As a result, the modeling of the Es layer is very important for the accuracy, reliability, and further applications of modern real‐time global navigation satellite system precise point positioning. In this study, we have constructed an empirical model of the Es layer using the multivariable nonlinear least‐squares‐fitting method, based on the S4max from Constellation Observing System for Meteorology, Ionosphere, and Climate satellite radio occultation measurements in the period 2006–2014. The model can describe the climatology of the intensity of Es layers as a function of altitude, latitude, longitude, universal time, and day of year. To validate the model, the outputs of the model were compared with ionosonde data. The correlation coefficients of the hourly foEs and the daily maximum foEs between the ground‐based ionosonde observations and model outputs at Beijing are 0.52 and 0.68, respectively. The model can give a global climatology of the intensity of Es layers and the seasonal variations of Es layers, although the Es layers during the summer are highly variable and difficult to accurately predict. The outputs of the model can be implemented in comprehensive models for a description of the climatology of Es layers and provide relatively accurate information about the global variation of Es layers.

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Section: Model Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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An Empirical Model of the Ionospheric Sporadic E Layer Based on GNSS Radio Occultation Data

Xue

Scott

et al. 2022

Space Weather

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“…In fact, such a temporal lag represents the average of the broadly distributed shift times between the two datasets, or, in other words, the time required for the various geo-effective structures to transit from L1 to the Earth. The signature of the 27-day solar rotation is evident in the secondary peaks observed during the minimum period [32,33]. Therefore, to determine the influence of the SW energy on geo-effectiveness, in the following analysis, the energy time series are shifted backward by a time interval with respect to the Dst index: E(t) = E(t + ).…”

Section: Methodsmentioning

confidence: 99%

Modulation of Solar Wind Impact on the Earth’s Magnetosphere during the Solar Cycle

et al. 2022

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The understanding of extreme geomagnetic storms is one of the key issues in space weather. Such phenomena have been receiving increasing attention, especially with the aim of forecasting strong geomagnetic storms generated by high-energy solar events since they can severely perturb the near-Earth space environment. Here, the disturbance storm time index Dst, a crucial geomagnetic activity proxy for Sun–Earth interactions, is analyzed as a function of the energy carried by different solar wind streams. To determine the solar cycle activity influence on Dst, a 12-year dataset was split into sub-periods of maximum and minimum solar activity. Solar wind energy and geomagnetic activity were closely correlated for both periods of activity. Slow wind streams had negligible effects on Earth regardless of their energy, while high-speed streams may induce severe geomagnetic storming depending on the energy (kinetic or magnetic) carried by the flow. The difference between the two periods may be related to the higher rate of geo-effective events during the maximum activity, where coronal mass ejections represent the most energetic and geo-effective driver. During the minimum period, despite a lower rate of high energetic events, a moderate disturbance in the Dst index can be induced.

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“…If they reach down to the heliographic latitude of Earth, they sweep over the Earth once per solar rotation and cause a sequence of effects with a roughly 27‐day periodicity. These effects include recurrent geomagnetic storms (Chi et al., 2018; Echer et al., 2013; Jian et al., 2006), changes in the energetic particle environment on Earth (Rouillard & Lockwood, 2007), in the ionosphere (Yu et al., 2021), in the occurrence of lightning (C. J. Scott et al., 2014), and other meteorological processes in Earth's lower atmosphere (Harrison & Lockwood, 2020). In rare cases, CIRs can also cause intense geomagnetic storms (Chi et al., 2018; Gonzalez et al., 2011).…”

Section: Introductionmentioning

confidence: 99%

Predictive Capabilities of Corotating Interaction Regions Using STEREO and Wind In‐Situ Observations

et al. 2022

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Hazardous space weather endangers Earth's geomagnetic environment, causes geomagnetic storms, and poses a threat to satellite systems, radio communications, electrical transmission, and technological critical infrastructure (Cannon et al., 2013;Hapgood, 2011). As people become more reliant on modern technology, predicting space weather is becoming more important. Stream Interaction Regions (SIRs) are solar wind structures formed between the fast solar wind stream originating from coronal holes and the high-density, low-speed wind from the streamer belt. The SIRs are also referred as Corotating Interaction Regions (CIRs, [Gosling & Pizzo, 1999]) when they recur on successive solar rotations. CIRs are the main sources of moderate and minor recurrent geomagnetic

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A Signature of 27 day Solar Rotation in the Concentration of Metallic Ions within the Terrestrial Ionosphere

Cited by 13 publications

References 85 publications

An Empirical Model of the Ionospheric Sporadic E Layer Based on GNSS Radio Occultation Data

An Empirical Model of the Ionospheric Sporadic E Layer Based on GNSS Radio Occultation Data

Modulation of Solar Wind Impact on the Earth’s Magnetosphere during the Solar Cycle

Predictive Capabilities of Corotating Interaction Regions Using STEREO and Wind In‐Situ Observations

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