On the MLT distribution of <i>F</i> region polar cap patches at night

Moen, J.; Gulbrandsen, Njål; Lorentzen, D. A.; Carlson, H. C.

doi:10.1029/2007gl029632

Cited by 79 publications

(109 citation statements)

References 28 publications

(38 reference statements)

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“…Mitchell et al (2005) found phase and amplitude scintillations to be colocated with strong gradients in the Total Electron Content (TEC) at the edges of the high electron density streams. Furthermore, scintillation climatology studies by Spogli et al (2009) demonstrated enhanced scintillation levels around magnetic midnight, which were consistent with the Magnetic Local Time (MLT) distribution of polar cap patches at night (Moen et al 2007). By comparing the GPS data with radio instruments, Prikryl et al (2010) claimed that the polar cap patches are the main contributors to scintillation-causing irregularities in the polar cap.…”

Section: Introductionmentioning

confidence: 55%

“…To conclude, the worst situation in the European Arctic sector can occur when polar cap patches are further structured by the substorm auroral arc dynamics, i.e., signal interferences with the auroral blob phenomenon around magnetic midnight. This can explain the scintillation climatology study by Spogli et al (2009) who attributed the scintillation peak around magnetic midnight to the statistical distribution of polar cap patches exiting the polar cap around magnetic midnight (Moen et al 2007). However, there is a need to carry out a statistical study to see if this is always true.…”

Section: Summary and Concluding Remarksmentioning

confidence: 97%

“…From around 18:30 UT to 23:00 UT, we find a sequence of six inverted integral signs in the keogram (denoted by A-F in Fig. 1a), which is a feature of polar cap patches travelling across the FOV from north to south (Lorentzen et al 2004;Moen et al 2007). From 20:00 UT to 22:00 UT, the auroral boundary moved poleward, stopped and retreated equatorward several times, which is an auroral signature of transient tail reconnection followed by boundary relaxation (Lorentzen et al 2004;Cowley & Lockwood 1992;Moen et al 2007).…”

Section: Observationsmentioning

confidence: 99%

“…1a), which is a feature of polar cap patches travelling across the FOV from north to south (Lorentzen et al 2004;Moen et al 2007). From 20:00 UT to 22:00 UT, the auroral boundary moved poleward, stopped and retreated equatorward several times, which is an auroral signature of transient tail reconnection followed by boundary relaxation (Lorentzen et al 2004;Cowley & Lockwood 1992;Moen et al 2007). Several polar cap patches crossed the open/closed magnetic field line boundary and exited into the nightside auroral oval, where they changed their status to auroral blobs (Crowley et al 2000).…”

Section: Observationsmentioning

confidence: 99%

See 3 more Smart Citations

GPS scintillation effects associated with polar cap patches and substorm auroral activity: direct comparison

Jin

Moen

Miloch

2014

J. Space Weather Space Clim.

102

136

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We directly compare the relative GPS scintillation levels associated with regions of enhanced plasma irregularities called auroral arcs, polar cap patches, and auroral blobs that frequently occur in the polar ionosphere. On January 13, 2013 from Ny-Å lesund, several polar cap patches were observed to exit the polar cap into the auroral oval, and were then termed auroral blobs. This gave us an unprecedented opportunity to compare the relative scintillation levels associated with these three phenomena. The blobs were associated with the strongest phase scintillation (r / ), followed by patches and arcs, with r / up to 0.6, 0.5, and 0.1 rad, respectively. Our observations indicate that most patches in the nightside polar cap have produced significant scintillations, but not all of them. Since the blobs are formed after patches merged into auroral regions, in space weather predictions of GPS scintillations, it will be important to enable predictions of patches exiting the polar cap.

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Section: Introductionmentioning

confidence: 55%

Section: Summary and Concluding Remarksmentioning

confidence: 97%

Section: Observationsmentioning

confidence: 99%

Section: Observationsmentioning

confidence: 99%

See 2 more Smart Citations

GPS scintillation effects associated with polar cap patches and substorm auroral activity: direct comparison

Jin

Moen

Miloch

2014

J. Space Weather Space Clim.

102

136

View full text Add to dashboard Cite

show abstract

“…Two subsets of discrete polar aurora include polar cap arcs and polar cap patches. Polar cap arcs occur during quiet magnetic activity and northward IMF (Zhu et al 1997) and are 4 times more common in magnetic dawn than dusk (Hosokawa et al 2011), while polar cap patches exhibit a maximum at 23 hr MLT with intensities several times that of airglow (typically 1 kR; McEwen & Harrington 1991;Moen et al 2007).…”

Section: Review Of Airglow and Aurorae Variabilitymentioning

confidence: 99%

Airglow and Aurorae from Dome A, Antarctica

et al. 2012

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Despite the absence of artificial light pollution at Antarctic plateau sites such as Dome A, other factors such as airglow, aurorae and extended periods of twilight have the potential to adversely affect optical observations. We present a statistical analysis of the airglow and aurorae at Dome A using spectroscopic data from Nigel, an optical/near-IR spectrometer operating in the 300–850 nm range. The median auroral contribution to the B, V and R photometric bands is found to be 22.9, 23.4 and 23.0 mag arcsec−2 respectively. We are also able to quantify the amount of annual dark time available as a function of wavelength; on average twilight ends when the Sun reaches a zenith distance of 102.6°.

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Spatial variability in the ionosphere measured with GNSS networks

et al. 2013

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Traveling ionospheric disturbances (TIDs) appear as medium‐scale TIDs at midlatitudes and as polar cap patches at high latitudes. Both can have a negative impact on Global Navigation Satellite Systems (GNSS) measurements, although the amplitude is of tenths of a total electron content unit (TECU), 1 TECU = 1016 el m−2. Due to their spatial extension, they affect GNSS measurements using receivers separated with distances up to ~1000 km. We present statistical measures of the ionospheric spatial variability as functions of time in solar cycle, annual season, and time of day for different geographical locations in Europe. In order to perform this spatial characterization of the ionosphere, we have used archived GPS data from a 13 year period, 1999–2011, covering a complete solar cycle. We find that the ionospheric spatial variability is larger for the northern areas than for the southern areas. This is especially pronounced at solar maximum. For the more northern areas, the ionospheric variability is greater during nighttime than during daytime, while for central Europe, the variability is larger during daytime. At solar maximum, the variability is larger during the months October and November and smaller in June and July.

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On the MLT distribution of F region polar cap patches at night

Cited by 79 publications

References 28 publications

GPS scintillation effects associated with polar cap patches and substorm auroral activity: direct comparison

GPS scintillation effects associated with polar cap patches and substorm auroral activity: direct comparison

Airglow and Aurorae from Dome A, Antarctica

Spatial variability in the ionosphere measured with GNSS networks

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