L-band scintillations and calibrated total electron content gradients over Brazil during the last solar maximum

Claudio Cesaroni,Luca Spogli,Joao Francisco Galera Monico,Giorgiana De Franceschi,Vincenzo Romano,Lucilla Alfonsi,Carlo Scotto,Luigi Ciraolo,Bruno Bougard,Marcio Aquino

doi:10.1051/swsc/2015038

Abstract

This work presents a contribution to the understanding of the ionospheric triggering of L-band scintillation in the region over São Paulo state in Brazil, under high solar activity. In particular, a climatological analysis of Global Navigation Satellite Systems (GNSS) data acquired in 2012 is presented to highlight the relationship between intensity and variability of the total electron content (TEC) gradients and the occurrence of ionospheric scintillation. The analysis is based on the GNSS data acquired by a dense distribution of receivers and exploits the integration of a dedicated TEC calibration technique into the Ground Based Scintillation Climatology (GBSC), previously developed at the Istituto Nazionale di Geofisica e Vulcanologia. Such integration enables representing the local ionospheric features through climatological maps of calibrated TEC and TEC gradients and of amplitude scintillation occurrence. The disentanglement of the contribution to the TEC variations due to zonal and meridional gradients conveys insight into the relation between the scintillation occurrence and the morphology of the TEC variability. The importance of the information provided by the TEC gradients variability and the role of the meridional TEC gradients in driving scintillation are critically described.

Highlights

Global Navigation Satellite Systems (GNSS) provide continuous position, navigation and time information worldwide
It can be noted that, regardless of the season, the larger values of hTECi are located around 15° S magnetic latitude. This is a signature of the enhancement of ionization, that identifies the southern crest of the Equatorial Ionization Anomaly (EIA)
This study presents how, by disentangling the contribution to the total electron content (TEC) variations due to zonal and meridional gradients, it is possible to learn more about the relation between the scintillation occurrence and the morphology of the TEC variability

Summary

Introduction

Global Navigation Satellite Systems (GNSS) provide continuous position, navigation and time information worldwide. GNSS data are of particular interest for ionospheric studies, because Space Weather conditions greatly influence GNSS integrity, accuracy and availability. The inhomogeneity of ionospheric electron distribution can cause sudden, rapid and irregular fluctuations of the amplitude and phase of the received signals, in an effect termed ‘‘ionospheric scintillation’’ (Wernik & Liu 1974). Scintillation can cause degradation on GNSS measurements and, in the worst case, can lead to a signal loss of lock to the satellite, affecting the availability of the service and potentially leading to outages that could last from minutes to hours. High sampling frequency (50 Hz) receivers for scintillation monitoring, the time intervals in which such indices are calculated are of 60 s for S4 and 1, 3, 10, 30 and 60 s for r/

Objectives

Results

Conclusion