Study of the ionospheric total electron content response to the great flare on 15 April 2001 using the International GPS Service network for the whole sunlit hemisphere

Zhang, D. H.; Xiao, Zuo

doi:10.1029/2002ja009822

Cited by 40 publications

(40 citation statements)

References 43 publications

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“…[17] It has been well known that solar flare-induced SITEC values depend on the SZA [Zhang and Xiao, 2003;Tsurutani et al, 2005;Wan et al, 2005]. Tsugawa et al [2006a] statistically analyzed 91 SITEC events from January 2000 to May 2005 using the worldwide GPS receiver network and revealed that the SITEC value is linearly dependent on the cosine of SZA with nonnegligible residuals in almost all the flare events.…”

Section: Discussionmentioning

confidence: 99%

“…Since the beginning of 21st century, the twodimensional imaging technique using TEC data from worldwide GPS receiver networks has been applied to SITEC studies [e.g., Afraimovich et al, 2001;Liu and Lin, 2004]. These studies have observed a solar zenith angle (SZA) dependence of SITEC [Zhang and Xiao, 2003;Wan et al, 2005]. Tsugawa et al [2006a] statistically analyzed 91 clear SITEC events from January 2000 to May 2005 and revealed the summer-winter hemispheric asymmetry (SWHA) of SITEC is due to that of the O/N 2 density ratio in the ionospheric F region.…”

Section: Introductionmentioning

confidence: 99%

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Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N₂ ratio: Solar activity dependence

et al. 2007

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[1] The solar activity dependence of the summer-winter hemispheric asymmetry (SWHA) of the sudden increase in total electron content (SITEC) due to solar flares and of the O/N 2 ratio is statistically analyzed using global GPS-total electron content data and TIMED Global Ultraviolet Imager column O/N 2 ratio data. We focus on observations with nonnegligible residuals of the solar zenith angle (SZA) dependency of SITEC. We

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N₂ ratio: Solar activity dependence

et al. 2007

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“…Most ionosphere responses to solar flares have been attributed to, and can be explained by, the enhancement of solar X-rays and EUV during solar flares. For example, it has been found that total electron content (TEC) enhancement during solar flares primarily follows the cosine of solar zenith angle [Zhang and Xiao, 2003;Liu et al, 2007;. However, recent measurements have revealed phenomena that may not be attributable to or cannot be explained by solar irradiance and related physical and chemical processes.…”

Section: Introductionmentioning

confidence: 99%

Solar flare impacts on ionospheric electrodyamics

Qian

Burns

Solomon

et al. 2012

Geophysical Research Letters

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[1] The sudden increase of X-ray and extreme ultra-violet irradiance during flares increases the density of the ionosphere through enhanced photoionization. In this paper, we use model simulations to investigate possible additional contributions from electrodynamics, finding that the vertical E Â B drift in the magnetic equatorial region plays a significant role in the ionosphere response to solar flares. During the initial stage of flares, upward E Â B drifts weaken in the magnetic equatorial region, causing a weakened equatorial fountain effect, which in turn causes lowering of the peak height of the F 2 region and depletion of the peak electron density of the F 2 region. In this initial stage, total electron content (TEC) enhancement is predominantly determined by solar zenith angle control of photoionization. As flares decay, upward E Â B drifts are enhanced in the magnetic equatorial region, causing increases of the peak height and density of the F 2 region. This process lasts for several hours, causing a prolonged F 2 -region disturbance and TEC enhancement in the magnetic equator region in the aftermath of flares. During this stage, the global morphology of the TEC enhancement becomes predominantly determined by these perturbations to the electrodynamics of the ionosphere.

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“…Secondly, the duration of TEC enhancements is lasting several hours, that is much longer than the flare duration. On the other hand, a high correlation was found between the rate of TEC variations and hard X-ray variations observed by Yohkoh in the band of 53-93 keV (Afraimovich et al, 2001;Zhang and Xiao, 2003). In other words, the fast TEC variations are closely related to the solar hard electro- magnetic emission while their gradual changes are different.…”

Section: Introductionmentioning

confidence: 90%

Top-side ionosphere response to extreme solar events

et al. 2006

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Abstract. Strong X-flares and solar energetic particle (SEP) fluxes are considered as sources of topside ionospheric disturbances observed by the ROCSAT-1/IPEI instrument during the Bastille Day event on 14 July 2000 and the Halloween event on 28 October-4 November 2003. It was found that within a prestorm period in the dayside ionosphere at altitudes of ∼600 km the ion density increased up to ∼80% in response to flare-associated enhancements of the solar X-ray emission. Ionospheric response to the SEP events was revealed both at sunlit and nightside hemispheres, where the ion density increased up to ∼40% and 100%, respectively. We did not find any prominent response of the ion temperature to the X-ray and SEP enhancements. The largest X-ray and SEP impacts were found for the X17 solar flare on 28 October 2003, which was characterized by the most intense fluxes of solar EUV and relativistic solar particles (Veselovsky et al., 2004). Solar events on 14 July 2000 and 29 October 2003 demonstrate weaker impacts with respect to their X-ray and SEP intensities. The weakest ionospheric response is observed for the limb X28 solar flare on 4 November 2003. The topside ionosphere response to the extreme solar events is interpreted in terms of the short-duration impact of the solar electromagnetic radiation and the long-lasting impact of the SEP.

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Study of the ionospheric total electron content response to the great flare on 15 April 2001 using the International GPS Service network for the whole sunlit hemisphere

Cited by 40 publications

References 43 publications

Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N₂ ratio: Solar activity dependence

Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N₂ ratio: Solar activity dependence

Solar flare impacts on ionospheric electrodyamics

Top-side ionosphere response to extreme solar events

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Study of the ionospheric total electron content response to the great flare on 15 April 2001 using the International GPS Service network for the whole sunlit hemisphere

Cited by 40 publications

References 43 publications

Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N2 ratio: Solar activity dependence

Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N2 ratio: Solar activity dependence

Solar flare impacts on ionospheric electrodyamics

Top-side ionosphere response to extreme solar events

Contact Info

Product

Resources

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Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N₂ ratio: Solar activity dependence

Summer‐winter hemispheric asymmetry of the sudden increase in ionospheric total electron content and of the O/N₂ ratio: Solar activity dependence