Does the Peak Response of the Ionospheric <i>F</i><sub>2</sub> Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?

Ren, Dexin; Lei, Jiuhou; Wang, Wenbin; Burns, A. G.; Luan, Xiaoli; Dou, Xiankang

doi:10.1029/2018ja025835

Cited by 30 publications

(78 citation statements)

References 38 publications

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“…Transport is one of the most critical parameters that control the behavior of the ionosphere. These results suggest that interannual variability depends not only on the solar activity but also on several other physical processes such as geomagnetic activity (Rich et al, 2003) and local ionospheric parameters such as neutral wind and lower atmospheric forcing through the vertical coupling. Lee et al (2012) analyzed electron density measurements from CHAMP and GRACE along with Global Ionosphere Maps (GIM) TEC maps in relation to the F10.7 index and showed the spatial distribution of delay and correlation coefficient during the years 2003 to 2007.…”

Section: Spatial Distribution Of the Ionospheric Response Timementioning

confidence: 84%

“…There is a tendency that during high solar activity, the delay is increased slightly at low latitudes, but strongly (up to 3 d) in the high-latitude region. A negative delay is observed during low solar activity, presumably associated with the meteorological effects as suggested by Ren et al (2018). Another possible reason is ionospheric saturation, which might reduce the transport process during high solar activity due to lower recombination rates.…”

Section: Spatial Distribution Of the Ionospheric Response Timementioning

confidence: 86%

“…To understand the underlying mechanisms of the delay observed in the ionospheric plasma, Jakowski et al (1991) used a one-dimensional numerical model to explain the ionospheric delay of about 1-2 d. They concluded that the ionospheric delay could be attributed to the delayed atomic oxygen density variation at 180 km height produced via O 2 photodissociation. Ren et al (2018) performed multiple numerical experiments using the Thermosphere-Ionosphere Electrodynamics General Circulation Model (TIE-GCM) to investigate the potential physical mechanisms responsible for the ionospheric delay. Their simulation results revealed that photochemical, dynamic, and electrodynamic processes, as well as the geomagnetic activity, can be associated with the ionosphere response time.…”

Section: Trends In the Ionospheric Response To Solar Euv Variationsmentioning

confidence: 99%

“…The interaction of solar radiation with the ionosphere is complicated due to several mechanisms with the potential to modulate the thermosphere-ionosphere (T-I) system at different timescales ranging from the 11-year solar cycle down to minutes (e.g., Liu et al, 2003;Afraimovich et al, 2008;Liu and Chen, 2009;Chen et al, 2012). The ionosphere plasma response to solar EUV and UV variations has been widely studied using ground-and space-based observations (e.g., Jakowski et al, 1991;Jacobi et al, 2016;Schmölter et al, 2018;Jakowski et al, 1999), as well as by numerical and empirical modeling (e.g., Ren et al, 2018;Vaishnav et al, 2018a, b). These studies have shown that the response of the ionosphere to solar EUV radiation variations is delayed by 1-2 d at the 27 d solar rotation period (e.g., Jakowski et al, 1991;Afraimovich et al, 2008;Jakowski et al, 2002;Min et al, 2009;Jacobi et al, 2016;Lee et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Long-term trends in the ionospheric response to solar extreme-ultraviolet variations

2019

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Abstract. The thermosphere–ionosphere system shows high complexity due to its interaction with the continuously varying solar radiation flux. We investigate the temporal and spatial response of the ionosphere to solar activity using 18 years (1999–2017) of total electron content (TEC) maps provided by the international global navigation satellite systems service and 12 solar proxies (F10.7, F1.8, F3.2, F8, F15, F30, He II, Mg II index, Ly-α, Ca II K, daily sunspot area (SSA), and sunspot number (SSN)). Cross-wavelet and Lomb–Scargle periodogram (LSP) analyses are used to evaluate the different solar proxies with respect to their impact on the global mean TEC (GTEC), which is important for improved ionosphere modeling and forecasts. A 16 to 32 d periodicity in all the solar proxies and GTEC has been identified. The maximum correlation at this timescale is observed between the He II, Mg II, and F30 indices and GTEC, with an effective time delay of about 1 d. The LSP analysis shows that the most dominant period is 27 d, which is owing to the mean solar rotation, followed by a 45 d periodicity. In addition, a semi-annual and an annual variation were observed in GTEC, with the strongest correlation near the equatorial region where a time delay of about 1–2 d exists. The wavelet variance estimation method is used to find the variance of GTEC and F10.7 during the maxima of the solar cycles SC 23 and SC 24. Wavelet variance estimation suggests that the GTEC variance is highest for the seasonal timescale (32 to 64 d period) followed by the 16 to 32 d period, similar to the F10.7 index. The variance during SC 23 is larger than during SC 24. The most suitable proxy to represent solar activity at the timescales of 16 to 32 d and 32 to 64 d is He II. The Mg II index, Ly-α, and F30 may be placed second as these indices show the strongest correlation with GTEC, but there are some differences in correlation during solar maximum and minimum years, as the behavior of proxies is not always the same. The indices F1.8 and daily SSA are of limited use to represent the solar impact on GTEC. The empirical orthogonal function (EOF) analysis of the TEC data shows that the first EOF component captures more than 86 % of the variance, and the first three EOF components explain 99 % of the total variance. EOF analysis suggests that the first component is associated with the solar flux and the third EOF component captures the geomagnetic activity as well as the remaining part of EOF1. The EOF2 captures 11 % of the total variability and demonstrates the hemispheric asymmetry.

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Section: Spatial Distribution Of the Ionospheric Response Timementioning

confidence: 84%

Section: Spatial Distribution Of the Ionospheric Response Timementioning

confidence: 86%

Section: Trends In the Ionospheric Response To Solar Euv Variationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Long-term trends in the ionospheric response to solar extreme-ultraviolet variations

2019

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“…where t stands for the time in unit of days, and F10.7 is in the unit of solar flux unit (sfu). The model setting in this study makes it sure that the contribution from the 27-day solar EUV flux change to thermospheric temperature can be isolated, as is described in Ren et al (2018) in detail.…”

Section: Methodology and Model Descriptionmentioning

confidence: 99%

A Simulation Study on the Time Delay of Daytime Thermospheric Temperature Response to the 27‐Day Solar EUV Flux Variation

et al. 2019

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In this study, the National Center for Atmospheric Research Thermosphere Ionosphere Electrodynamic General Circulation Model is used to explore the physical mechanisms of the time delay of daytime thermospheric temperature response to the 27-day solar extreme ultraviolet (EUV) flux variation. The contributions from different physical processes to the time delay of thermospheric temperature response, the peak perturbation of the thermospheric temperature with respect to the peak of 27-day solar EUV flux variation, were examined by diagnostically analyzing the thermospheric energy equation in a fixed local time frame. It was found that the time delay of the thermospheric temperature response to the 27-day solar EUV flux variation corresponds to the time needed for the total heating and cooling rates to be balanced. This time is slightly later than the times of the peaks of both the heating and cooling rates. Furthermore, the global circulation in the upper atmosphere plays a significant role in the delayed response of thermospheric temperature to solar EUV flux variations. Our simulation results show that the time delay of thermospheric temperature response to the 27-day solar EUV flux variation is about 0.5-0.8 day, depending on the amplitude of solar EUV flux variations. Key Points: • The time delay of daytime thermospheric temperature response to 27-day EUV flux variations is 0.5-0.8 day • The time delay of thermospheric temperature response corresponds to the time needed for the heating rate and the cooling rate to be balanced • The time delay of thermospheric temperature response to 27-day EUV flux variations is modulated by the thermospheric circulation

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Day‐to‐Day Variability of the Thermosphere and Ionosphere

Liu

Yamazaki

Lei

2021

Geophysical Monograph Series

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Does the Peak Response of the Ionospheric F₂ Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?

Cited by 30 publications

References 38 publications

Long-term trends in the ionospheric response to solar extreme-ultraviolet variations

Long-term trends in the ionospheric response to solar extreme-ultraviolet variations

A Simulation Study on the Time Delay of Daytime Thermospheric Temperature Response to the 27‐Day Solar EUV Flux Variation

Day‐to‐Day Variability of the Thermosphere and Ionosphere

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Does the Peak Response of the Ionospheric F2 Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?

Cited by 30 publications

References 38 publications

Long-term trends in the ionospheric response to solar extreme-ultraviolet variations

Long-term trends in the ionospheric response to solar extreme-ultraviolet variations

A Simulation Study on the Time Delay of Daytime Thermospheric Temperature Response to the 27‐Day Solar EUV Flux Variation

Day‐to‐Day Variability of the Thermosphere and Ionosphere

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Does the Peak Response of the Ionospheric F₂ Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?