Calibrating estimates of ionospheric long-term change

Christopher John Scott, Matthew N. Wild, Luke Anthony Barnard, Bingkun Yu, Tatsuhiro Yokoyama, Michael Lockwood, Cathryn Mitchell, John Coxon, Andrew J. Kavanagh

Research output: Contribution to journalArticlepeer-review

Abstract

Long-term reduction (∼20km) in the height of the ionospheric F2 layer, hmF2, is predicted to result from increased levels of tropospheric greenhouse gases. Sufficiently long sequences of ionospheric data exist in order for us to investigate this long-term change, recorded by a global network of ionosondes. However, direct measurements of ionospheric-layer height with these instruments is not possible. As a result, most estimates of hmF2 rely on empirical formulae based on parameters routinely scaled from ionograms. Estimates of trends in hmF2 using these formulae show no global consensus. We present an analysis in which data from the Japanese ionosonde station at Kokubunji were used to estimate monthly median values of hmF2 using an empirical formula. These were then compared with direct measurements of the F2 layer height determined from incoherent-scatter measurements made at the Shigaraki MU Observatory, Japan. Our results reveal that the formula introduces diurnal, seasonal, and long-term biases in the estimates of hmF2 of ≈±10% (±25km at an altitude of 250km). These are of similar magnitude to layer height changes anticipated as a result of climate change. The biases in the formula can be explained by changes in thermospheric composition that simultaneously reduce the peak density of the F2 layer and modulate the underlying F1 layer ionization. The presence of an F1 layer is not accounted for in the empirical formula. We demonstrate that, for Kokobunji, the ratios of F2 / E and F2 / F1 critical frequencies are strongly controlled by changes in geomagnetic activity represented by the am index. Changes in thermospheric composition in response to geomagnetic activity have previously been shown to be highly localized. We conclude that localized changes in thermospheric composition modulate the F2 / E and F2 / F1 peak ratios, leading to differences in hmF2 trends. We further conclude that the influence of thermospheric composition on the underlying ionosphere needs to be accounted for in these empirical formulae if they are to be applied to studies of long-term ionospheric change.

Original languageEnglish
Pages (from-to)395-418
Number of pages24
JournalAnnales Geophysicae
Volume42
Issue number2
Early online date24 Sept 2024
DOIs
Publication statusPublished - 24 Sept 2024

Data Availability Statement

Software used in the analysis of these data is available via Scott (2024) https://doi.org/10.5281/zenodo.12799715. MU radar data were provided by the Research Institute for Sustainable Humanosphere of Kyoto University and can be obtained from their website at https://www.rish.kyoto-u.ac.jp/mu/isdata/ (MU Radar Management Group, 2024). Ionospheric data used in this analysis are available via the UK Solar System Data Centre at https://www.ukssdc.ac.uk (Wild, 2021).

Acknowledgements

The authors would like to thank the Research Institute for Sustainable Humanosphere of Kyoto University for providing the MU radar data; the WDC for Ionosphere and Space Weather, Tokyo, National Institute of Information and Communications Technology for providing the Kokubunji ionosonde data, which were also made available through the UK Solar System Data Centre.

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