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Solar Wind and Geomagnetic Conditions that Lead to the Largest Relativistic Electron Fluxes in GPS Orbit
GB/NERC/BAS/PDC/02088

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Summary

Abstract:
Relativistic electrons are an important space weather hazard, being a major source of radiation damage to satellites and posing a risk to humans in space. We use approximately 20 years of data from the US Global Positioning System (GPS) satellite NS41 to determine the characteristics of the geomagnetic storms that lead to the largest relativistic electron fluxes in GPS orbit. The largest CME-driven events are associated with the solar wind having negative excursions of the IMF Bz with minimum values of ~-14 nT two hours prior to zero epoch, defined as the time of the minimum in the Dst index and strong Dst minima, reaching ~-130 nT at zero epoch. In contrast, events driven by high speed solar wind streams (HSSs) are associated with smaller negative excursions of IMF Bz with minimum values of ~-4 nT two hours prior to zero epoch and moderate Dst minima, reaching ~-60 nT at zero epoch. Compared with HSS-driven events, peak E = 2.0 MeV fluxes associated with CME-driven events are larger by factors of 1.3 at L=4.5 and 2.4 at L=6.5. Both the CME- and HSS-driven events are associated with enhancements in the solar wind number density and pressure prior to zero epoch. Following zero epoch the solar wind number density and pressure become low and substorm activity is enhanced for several days.

Keywords:
Geomagnetic storms, Medium Earth orbit, Relativistic electrons

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Citation

Meredith, N., Bortnik, J., Hua, M., Cayton, T., Clilverd, M., Daggitt, T., & Bunting, K. (2025). Solar Wind and Geomagnetic Conditions that Lead to the Largest Relativistic Electron Fluxes in GPS Orbit (Version 1.0) [Data set]. NERC EDS UK Polar Data Centre. https://doi.org/10.5285/b6d3de94-c1db-42f6-9342-061f6b74d99c

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Basic Information

Creation Date: 2025-10-01
Dataset Progress: Complete
Dataset Language: English
ISO Topic Categories:  
  • Geoscientific Information
Parameters:
  • Sun-earth Interactions > Ionosphere/Magnetosphere Dynamics > Magnetic Storms
  • Sun-earth Interactions > Solar Energetic Particle Flux > Electron Flux
Personnel:
Name Dr Nigel Meredith
Role(s) Metadata Author, Investigator
Organisation British Antarctic Survey
   
Name Prof Jacob Bortnik
Role(s) Investigator
Organisation UCLA
   
Name Dr Man Hua
Role(s) Investigator
Organisation UCLA
   
Name Dr Thomas E Cayton
Role(s) Investigator
Organisation Retired
   
Name Dr Mark A Clilverd
Role(s) Investigator
Organisation British Antarctic Survey
   
Name Dr Thomas A Daggitt
Role(s) Investigator
Organisation British Antarctic Survey
   
Name Dr Kaine A Bunting
Role(s) Investigator
Organisation British Antarctic Survey
   
Parent Dataset: N/A

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Additional Information

Reference: Meredith, N. P., Bortnik, J., Hua, M., Cayton, T. E., Clilverd, M. A., Daggitt, T. A., & Bunting K. A. (2025). Solar Wind and Geomagnetic Conditions that Lead to the Largest Relativistic Electron Fluxes in GPS Orbit, Space Weather
Quality: The particle data have been calibrated and quality-controlled prior to release.
Lineage/Methodology: The data used in this study were collected by the Burst Detector Dosimeter IIR (BDD-IIR) on board the US GPS satellite NS41. The data is publicly available from http://www.ngdc.noaa.gov/stp/space-weather/satellite-data/satellite-systems/gps/data/ns41. Full details of the subsequent analysis are given in Meredith et al. (2025).

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Locality

Temporal Coverage:
Start Date 2000-12-10
End Date 2020-07-25
   
Data Resolution:
Latitude Resolution N/A
Longitude Resolution   N/A
Horizontal Resolution Range N/A
Vertical Resolution N/A
Vertical Resolution Range N/A
Temporal Resolution 4 minute resolution
Temporal Resolution Range Weekly - < Monthly
   
Location:
Location Global
Detailed Location   N/A

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Instrumentation

Data Collection: BDD-IIR is a multi-purpose silicon detector system. It features 8 individual channels of a "shield/filter/sensor" design that permits the detector to sample roughly half the celestial sphere while at the same time shielding the silicon sensor elements from most of the incident particle flux.

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Storage

Distribution:
Distribution Media Online Internet (HTTP)
Distribution Size N/A
Distribution Format  ASCII
Fees N/A
   

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