Tidal forcing effects on the zonal variation of solstice equatorial plasma bubbles

Loren C. Chang, Cornelius Csar Jude H. Salinas, Yi Chung Chiu, Pei Yun Chiu, Charles C.H. Lin

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

Equatorial plasma bubbles are elongated plasma depletions that can occur in the nighttime ionospheric F region, causing scintillation in satellite navigation and communications signals, and manifesting in ionograms as spread F. Equatorial plasma bubbles are believed to be Rayleigh-Taylor instabilities seeded by vertically propagating gravity waves. A necessary pre-condition for plasma bubble formation is believed to be a threshold vertical ion drift from the E region, which is required to produce the vertical plasma gradients conducive to such an instability. Factors affecting the zonal and seasonal variation of equatorial plasma bubbles therefore include magnetic declination, as well as the strength of the equatorial electojet, and neutral winds in the lower thermosphere controlling vertical plasma drifts via the wind dynamo. In most longitude zones, the above factors result in elevated occurrence rates of equatorial plasma bubbles during the equinoxes. The notable exception is over the central Pacific and African sectors, where equatorial plasma bubble activity maximizes during solstice. As the zonal separation of the two sectors is roughly half the Earth’s circumference, Tsunoda et al. (2015) [1] hypothesized that the solstice maxima in these two sectors could be driven by a zonal wavenumber 2 atmospheric tidal component in the mesosphere and lower thermosphere (MLT). In this study, we find that the post-sunset electron density observed by FORMOSAT-3/COSMIC during the boreal summer does indeed exhibit a wave-2 zonal distribution in both the equatorial and northern mid latitude regions. The equatorial wave-2 is consistent with results expected from elevated vertical ion drift over the Central Pacific and African sectors, while the mid- latitude wave-2 is consistent with the Mid-Summer Nighttime Anomaly. Using COSMIC, the seasonal, longitudinal, and local time variation of ionospheric tidal and stationary planetary wave (SPW) components that produce zonal wavenumber 2 disturbances when viewed in a constant local time frame is examined. Numerical experiments are also carried out using the Thermosphere Ionosphere Electrodynamics General Circulation Model (TIE-GCM) to determine the effect of the aforementioned tidal and SPW components on vertical ion drift, showing a clear wave-2 modulation of vertical ion drift when subject to forcing from wave-2 atmospheric tidal components in the mesosphere and lower thermosphere. The aforementioned results are consistent with the solstice maxima hypothesis.

Original languageEnglish
Title of host publicationION 2019 Pacific PNT Meeting Proceedings
PublisherThe Institute of Navigation
Pages846-853
Number of pages8
ISBN (Electronic)0936406224, 9780936406220
DOIs
Publication statusPublished - 2019
Externally publishedYes
EventInstitute of Navigation 2019 Pacific Positioning, Navigation and Timing Meeting, PACIFIC PNT 2019 - Honolulu, United States
Duration: 2019 Apr 82019 Apr 11

Publication series

NameProceedings of the Institute of Navigation Pacific Positioning, Navigation and Timing Meeting, Pacific PNT
Volume2019-April
ISSN (Print)2331-6284

Conference

ConferenceInstitute of Navigation 2019 Pacific Positioning, Navigation and Timing Meeting, PACIFIC PNT 2019
Country/TerritoryUnited States
CityHonolulu
Period19-04-0819-04-11

All Science Journal Classification (ASJC) codes

  • Transportation
  • Ocean Engineering
  • Aerospace Engineering
  • Electrical and Electronic Engineering
  • Computer Science Applications

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