The South Atlantic Anomaly throughout the solar cycle

Domingos, João; Jault, D.; Pais, Maria Alexandra; Mandea, Mioara

doi:10.1016/j.epsl.2017.06.004

Cited by 36 publications

(27 citation statements)

References 40 publications

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Section: Review Of Saa and Power Spectrum Analysismentioning

confidence: 99%

“…The research on the SAA throughout the solar cycle has been made by Domingos et al (2017). Evolution of the SAA particle flux can be seen as the result of two main effects, the secular variation of the Earth's magnetic field and the modulation of the protons density of the inner Van Allen radiation belt during the solar cycle (Domingos et al, 2017). In order to learn on the evolution of the particle flux anomaly, the method Principal Component Analysis (PCA) of either Polar Orbiting Environmental Satellites particle flux or Cloud-Aerosol Lidar with Orthogonal Polarization dark noise has been applied.…”

Section: Review Of Saa and Power Spectrum Analysismentioning

confidence: 99%

“…The SAA region can be describe as a low intensity magnetic field region. Study has been made by Domingos (2017) on the impact of SAA on the space weather. One of the dangers to spacecraft in orbit around the Earth is the presence of large doses of radiation encountered in space (Schaefer et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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South Atlantic Anomalyduring ascending and maximum phase of solar cycle 24

Nasuddin

Abdullah

Hamid

2020

Preprint

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Abstract. For this research, four regions have been studied which are the South Atlantic Anomaly (SAA) region, low latitude region, middle latitude region and high latitude region. The active period which is the period when the geomagnetic storm occur chosen to be analyzed is on 6 August 2011 and 12 April 2014 and the normal period, a period when no geomagnetic storm happen is on 24 July 2011 and 14 May 2014. Year 2011 is chosen to be analyze in order to study the SAA region during the ascending phase of the solar cycle 24 and in year 2014, where the occurrence of the maximum phase of solar cycle 24 occur. The research is carried since there is no clear characterization of the SAA during ascending as well as maximum phase based on power spectrum analysis method. The Earth's magnetic field component chosen to be analyzed is the horizontal intensity (H) due to its sensitiveness regarding geomagnetic activeness. From the research conducted, the result reveal SAA region has a tendency to be persistent during both period compare to other region during both phases. Other regions in the research experience a tendency to be persistent and antipersistent.

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Section: Review Of Saa and Power Spectrum Analysismentioning

confidence: 99%

Section: Review Of Saa and Power Spectrum Analysismentioning

confidence: 99%

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South Atlantic Anomalyduring ascending and maximum phase of solar cycle 24

Nasuddin

Abdullah

Hamid

2020

Preprint

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“…Figure 3 displays the distribution of the world magnetic field, comparing the regions with high magnetic fields and lower magnetic fields. Domingos et al have found that the eccentric dipole is currently offset from the Earth's center by about 550 km in a direction approximately 220N, 1400E [5].…”

Section: Introductionmentioning

confidence: 99%

South Atlantic Anomaly, Ionospheric Signals from Seismic Events

Hagen¹,

Azevedo²

2020

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The purpose of this paper is to analyze the most significant events that occurred in the period 1996-2018 located under the South Atlantic Anomaly (SAA), where the earth's magnetic field is weaker and the trapped particles during the geomagnetic storms suffer decay over time. The time examined corresponds to the Solar Cycles 23 and 24; the area covered is defined by the following coordinates: 0N, −50S, 40E, −90W. Some significant events in this region reported Very Low Frequency (VLF) and Ultra Low Frequency (ULF) waves before the event, varying from minutes, hours, and even weeks before the earthquakes. Our study searches for a mechanism to explain why the crust creates electromagnetic signs detected at the ionosphere. Piezoelectric currents flow on the crust, combining with the magnetic field lines, temporarily producing pre-seismic electromagnetic pulses that are detected at the ionosphere prior to the events. The mechanism that allows electromagnetic signs to be detected at the ionosphere is also elucidated. These signs are brief, and they will cease with the beginning of the shock or shortly thereafter. However, some features contribute to making the signs impossible to detect, involving crust materials, location, magnitude, and depths. We suggest that these ionospheric events could happen for other kinds of hazard events, such as Volcanos.

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“…Anomaly (SAA), where high energy charged particles from the sun and cosmic rays trapped in the Van Allen belts come down to relatively low altitudes (Noel et al, 2014;Domingos et al, 2017). Because the CALIOP 10 photomultipliers (PMTs) are not shielded against cosmic radiation, when these charged particles strike the PMT dynode chain they can generate large noise excursions (i.e., "spikes") that appear at arbitrary altitudes throughout the measured profiles ).…”

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confidence: 99%

CALIPSO Lidar Calibration at 532 nm: Version 4 Nighttime Algorithm

Kar¹,

Vaughan²,

Lee³

et al. 2017

Preprint

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In this work we present the motivation for and the implementation of the version 4.1 nighttime 532 nm parallel channel calibration. The nighttime 532 nm calibration is the most fundamental calibration of CALIOP data, since all of CALIOP's other radiometric calibration procedures -i.e., the 532 nm daytime calibration and the 1064 nm calibrations during both nighttime and daytime -depend either directly or indirectly on the 532 nm nighttime calibration. The 25 accuracy of the 532 nm nighttime calibration is significantly improved by raising the molecular normalization altitude from 30-34 km to 36-39 km to substantially reduce stratospheric aerosol contamination. Due to the greatly reduced molecular number density and consequently reduced signal-to-noise ratio at the higher altitudes used to avoid aerosols, the signal is averaged over a larger number of samples. The new calibration procedure is shown to eliminate biases introduced in earlier versions and consequently leads to an improved representation of stratospheric aerosols. 30Validation results using airborne lidar measurements are also presented. Biases relative to collocated measurements acquired by the Langley Research Center (LaRC) airborne High Spectral Resolution Lidar (HSRL) are reduced from 3.6% ± 2.2% in the version 3 data set to 1.6% ± 2.4 % in the version 4.1 release. 35Atmos. Meas. Tech. Discuss., https://doi

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The South Atlantic Anomaly throughout the solar cycle

Cited by 36 publications

References 40 publications

South Atlantic Anomalyduring ascending and maximum phase of solar cycle 24

South Atlantic Anomalyduring ascending and maximum phase of solar cycle 24

South Atlantic Anomaly, Ionospheric Signals from Seismic Events

CALIPSO Lidar Calibration at 532 nm: Version 4 Nighttime Algorithm

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