A new electron density model of the plasmasphere for operational applications and services

Jakowski, N.; Hoque, Mohammed Mainul

doi:10.1051/swsc/2018002

Cited by 35 publications

(26 citation statements)

References 48 publications

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“…Numerically, fluxtube contents were similar to nighttime ionospheric total electron content in a column of 1‐cm 2 cross section below 1,000 km (typically a few × 10 12 e − /cm 2 ). More recent studies based on non‐whistler methods are consistent with such prior work (Gonzalez‐Casado et al, ; Jakowski & Hoque, ; Lee et al, ). One of the earliest findings about plasmaspheric fluxtube contents is that they have a pronounced seasonal dependence.…”

Section: Discussionsupporting

confidence: 82%

Modeling Stable Auroral Red (SAR) Arcs at Geomagnetic Conjugate Points: Implications for Hemispheric Asymmetries in Heat Fluxes

Mendillo

Wroten

2019

JGR Space Physics

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Stable auroral red (SAR) arcs provide opportunities to study inner magnetosphere‐ionosphere coupling at midlatitudes. An imaging system at a single‐site obtains evidence of seasonal variations in SAR arc brightness and occurrence rates using events widely separated in time, as observed during different geomagnetic storms. The first SAR arc observed using two all‐sky imagers at geomagnetic conjugate points described seasonal effects at the same time for the same storm (Martinis, Mendillo, et al., 2019, https://doi.org/10.1029/2018JA026018). Here we report on modeling studies that enable specification of the roles of local “receptor conditions” in each hemisphere, plus the division of driving energy from a single source region into conjugate ionospheres. The geomagnetic storm of 1 June 2013 produced SAR arcs observed by conjugate all‐sky imagers yielding 73 Rayleighs (R) at Millstone Hill (L = 2.64) in the summer hemisphere, and 300 R during local winter at Rothera (L = 2.92). With incoherent scatter radar data not available to specify input conditions, we offer a new simulation approach using non‐incoherent scatter radar observations to specify local receptor conditions. These include a combination of semiempirical models (International Reference Ionosphere and MSIS) calibrated by local ionosonde and DMSP satellite data. We find that the driving mechanism (heat conduction entering the ionosphere) is not an equal partition of energy from the ring current source region, but one that is weaker in the summer hemisphere where the local receptor conditions are poised to produce fainter SAR arcs. The relationship between SAR arcs and recently discovered STEVE events are discussed and require further study.

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Section: Discussionsupporting

confidence: 82%

Modeling Stable Auroral Red (SAR) Arcs at Geomagnetic Conjugate Points: Implications for Hemispheric Asymmetries in Heat Fluxes

Mendillo

Wroten

2019

JGR Space Physics

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“…Recently, an empirical global plasmasphere model has been added to the Neustrelitz model family. This is called the Neustrelitz Plasmasphere Model (Jakowski & Hoque, ) and is used to estimate the topside ionosphere and plasmaspheric density distribution. NEDM is composed of the ionosphere key parameter models Neustrelitz TEC Model, Neustrelitz Peak Density Model, and Neustrelitz Peak Height Model only driven by the solar radio flux index F10.7 that describes the solar activity level.…”

Section: Basic Equations For Estimating Spatial and Rapid Temporal Vamentioning

confidence: 99%

Estimation of Spatial Gradients and Temporal Variations of the Total Electron Content Using Ground‐Based GNSS Measurements

Jakowski

Hoque

2019

Space Weather

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Precision and safety of life applications of Global Navigation Satellite Systems require key information on space weather conditions in particular on the perturbation degree of the ionosphere. Such systems are particularly vulnerable against severe spatial gradients and rapid changes of the total electron content (TEC) measured along different satellite‐receiver links. To estimate spatial gradients and rapid temporal variations of ionospheric TEC, two approaches are discussed. The Gradient Ionosphere indeX (GIX) and the Sudden Ionospheric Disturbance indeX are able to estimate the perturbation degree of the ionosphere instantaneously without taking into account previous measurements. The capabilities and accuracy of the index approaches are demonstrated by simulations using a 3‐D electron density model of the ionosphere and plasmasphere in conjunction with realistic Global Navigation Satellite Signal constellations. Real data tests confirm the applicability of GIX and the related standard deviation GIX Sigma to monitor spatial gradients. Sudden Ionospheric Disturbance indeX is able to monitor rapid temporal variations of TEC as exemplified by using Global Navigation Satellite Signal measurements carried out during solar flare events. Both approaches could identify enhanced space weather impacts on precise point positioning and the European Geostationary Navigation Overlay Service. More comprehensive studies analyzing ionospheric storms in close dialogue with potential customers are needed to fully utilize the potential of these approaches to serve as objective ionospheric indices for scaling horizontal TEC gradients and rapid TEC variations in space weather services.

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“…Another important aspect in the space weather context is the contribution of the plasmasphere (the region of cold and dense plasma encircling the Earth and approximately corotating with it) to the Total Electron Content (TEC) of the ionosphere. Plasmasphere density variations may then cause Global Navigation Satellite System (GNSS) inaccuracies and communications problems (Jakowski & Hoque, 2018).The most dramatic changes in plasma density and in its spatial distribution occur during geomagnetic storms. In particular, during events of southward turning of the interplanetary magnetic field (IMF), the enhanced dawn-dusk convection electric field may significantly erode the nightside plasmasphere (e.g., Goldstein et al, 2003), bringing its boundary (the plasmapause) from the typical distance of 4-5 Earth radii (R E ) up to ∼2 R E for the most extreme events (e.g., Chi et al, 2000).…”

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confidence: 99%

Multi‐Instrument Characterization of Magnetospheric Cold Plasma Dynamics in the June 22, 2015 Geomagnetic Storm

et al. 2021

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Understanding the concentration and composition of the plasma populating the Earth's magnetosphere, its spatial distribution and its temporal variations, represent relevant information in the space weather context. First of all, the mass density determines the inertia of the plasma and consequently the magnetohydrodynamic (MHD) response of the magnetosphere to solar wind perturbations. It also determines the frequency of Ultra-Low-Frequency (ULF) waves which can energize radiation belt particles (e.g., Elkington et al., 1999). Also, the ion composition affects the growth and evolution of electromagnetic ion cyclotron (EMIC) waves (e.g., Denton et al., 2014) which are an important loss mechanism for radiation belt electrons (e.g., Shprits et al., 2008). Another important aspect in the space weather context is the contribution of the plasmasphere (the region of cold and dense plasma encircling the Earth and approximately corotating with it) to the Total Electron Content (TEC) of the ionosphere. Plasmasphere density variations may then cause Global Navigation Satellite System (GNSS) inaccuracies and communications problems (Jakowski & Hoque, 2018).The most dramatic changes in plasma density and in its spatial distribution occur during geomagnetic storms. In particular, during events of southward turning of the interplanetary magnetic field (IMF), the enhanced dawn-dusk convection electric field may significantly erode the nightside plasmasphere (e.g., Goldstein et al., 2003), bringing its boundary (the plasmapause) from the typical distance of 4-5 Earth radii (R E ) up to ∼2 R E for the most extreme events (e.g., Chi et al., 2000). At the same time, the dayside plasmasphere

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A new electron density model of the plasmasphere for operational applications and services

Cited by 35 publications

References 48 publications

Modeling Stable Auroral Red (SAR) Arcs at Geomagnetic Conjugate Points: Implications for Hemispheric Asymmetries in Heat Fluxes

Modeling Stable Auroral Red (SAR) Arcs at Geomagnetic Conjugate Points: Implications for Hemispheric Asymmetries in Heat Fluxes

Estimation of Spatial Gradients and Temporal Variations of the Total Electron Content Using Ground‐Based GNSS Measurements

Multi‐Instrument Characterization of Magnetospheric Cold Plasma Dynamics in the June 22, 2015 Geomagnetic Storm

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