Developing a Nowcasting Capability for X‐Class Solar Flares Using VLF Radiowave Propagation Changes.

Harriet E George,James B Brundell,Mark A Clilverd,Kathy Cresswell‐Moorcock,Neil R Thomson,Craig J Rodger

doi:10.1029/2019sw002297

Harriet E George, James B Brundell + Show 4 more

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https://doi.org/10.1029/2019sw002297

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Abstract

AbstractA technique for analyzing very low frequency (VLF) radiowave signals is investigated in order to achieve rapid, real‐time detection of large solar flares, through the monitoring of changes in VLF radio signal propagation conditions. The reliability of the use of VLF phase and amplitude perturbations to determine the X‐ray fluxes involved during 10 large solar flare events (>X1) is examined. Linear regression analysis of signals from the NPM transmitter in Hawaii, received at Arrival Heights, Scott Base, Antarctica, over the years 2011–2015 shows that VLF phase perturbations during large solar flares have a 1.5–3 times lower mean square error when modeling the long wavelength X‐ray fluxes than the equivalent short wavelength fluxes. The use of VLF amplitude observations to determine long or short wavelength X‐ray flux levels have a 4–10 times higher mean square error than when using VLF phase. Normalized linear regression analysis identifies VLF phase as the most important parameter in the regression, followed by solar zenith angle at the midpoint of the propagation path, then the initial solar X‐ray flux level (from 5 min before the impact of the solar flare), with F10.7 cm flux from the day beforehand providing the least important contribution. Transmitter phase measurements are more difficult to undertake than amplitude. However, networks of VLF receivers already exist which include the high quality phase capability required for such a nowcasting product. Such narrowband VLF data can be a redundant source of flare monitoring if satellite data is not available.

Highlights

Solar flares are the first in a sequence of space weather events that have the potential to impact societal technologies, that is, disrupting GPS, and high frequency (HF) communications, as well as industries using them, that is, emergency responders, maritime mobile services, and the aviation industry
Linear regression analysis of signals from the NPM transmitter in Hawaii, received at Arrival Heights, Scott Base, Antarctica, over the years 2011–2015 shows that very low frequency (VLF) phase perturbations during large solar flares have a 1.5–3 times lower mean square error when modeling the long wavelength X‐ray fluxes than the equivalent short wavelength fluxes
Four other similar investigations were compared against NOAA XS flux measurements, again with two using VLF phase perturbations and two using VLF amplitude variations

Summary

Introduction

Solar flares are the first in a sequence of space weather events that have the potential to impact societal technologies, that is, disrupting GPS, and high frequency (HF) communications, as well as industries using them, that is, emergency responders, maritime mobile services, and the aviation industry. An example of the impact of large solar flares occurring in September 2017 on technological systems including navigation services over Europe is described by Berdermann et al (2018) and Redmon et al (2018). These studies report that a large X9.3 flare caused some loss of nominal positioning accuracy for aircraft and Global Navigation Satellite System (GNSS) navigation support services

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