PREDOMINANT TRAVELING IONOSPHERIC DISTURBANCES OVER EASTERN EUROPE DURING LOW LEVELS OF SOLAR AND GEOMAGNETIC ACTIVITIES USING INCOHERENT SCATTER RADAR DATA

PREDOMINANT TRAVELING IONOSPHERIC DISTURBANCES OVER EASTERN EUROPE DURING LOW LEVELS OF SOLAR AND GEOMAGNETIC ACTIVITIES USING INCOHERENT SCATTER RADAR DATA

PACS numbers: 92.60.hh,94.20.VvPurpose: Detection of wave processes of various temporal and spatial scales in the mid-latitude ionosphere over the Eastern Europe near the characteristic geophysical time periods (equinoxes and solstices) during magnetically quiet and weakly disturbed conditions at lo...

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Date:2020
Main Authors: Aksonova, K. D., Panasenko, S. V.
Format: Article
Language:rus
Published: Видавничий дім «Академперіодика» 2020
Subjects:
Key traveling ionospheric disturbances
magnetically quiet conditions
low solar activity
incoherent scatter radar
spectral and cross-correlation analysis
bandpass filtering
wave process characteristics
Online Access:http://rpra-journal.org.ua/index.php/ra/article/view/1331
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Journal Title:Radio physics and radio astronomy

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Radio physics and radio astronomy
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Summary:PACS numbers: 92.60.hh,94.20.VvPurpose: Detection of wave processes of various temporal and spatial scales in the mid-latitude ionosphere over the Eastern Europe near the characteristic geophysical time periods (equinoxes and solstices) during magnetically quiet and weakly disturbed conditions at low solar activity; estimation and calculation of traveling ionospheric disturbances (TIDs) characteristics based on the analysis of variations in the incoherent scatter radar signal power corresponding to electron density disturbances; analysis of TIDs generation sources.Design/methodology/approach: The time dependences of the incoherent scattering signal power were processed, and further bandpass filtering of data in various ranges of periods dominant modes was made. To remove slow signal variations (trend) and fast oscillations which may be caused by noise, the initial time series were passed through a digital filter with the wide bandwidth of 5–125 min. The spectral analysis was further made to localize the predominant oscillations on the time and period axes. Further, this range was divided into three subranges: 15–30, 30–60 and 60–120 min. For each of these subranges, the dominant TIDs were determined and their characteristics were estimated. Vertical components of phase velocity and disturbance wavelength were determined by the cross-correlation analysis, and their horizontal components were evaluated using the dispersion equation for acoustic-gravity waves (AGWs).Findings: Large and medium-scale TIDs were identified at altitudes from 100 to 400 km. The spectral analysis showed that for all the seasons the predominant quasi-periodic disturbances with periods within 60 to 120 min had the highest energy. The TIDs with periods within 15 to 120 min lasted from 2 to 10 h. We identified 59 TIDs in total. Most of them (49 events) were most likely associated with the AGW propagating upward (their sources were located at lower heights). The average values of large-scale perturbations in the subranges of 30-60 min (the average oscillation period being 45 min) and of 60-120 min (82 min): the maximum relative amplitude of variations – 0.14 and 0.20, respectively; the vertical phase velocity – 105 and 56 m/s; the horizontal phase velocity – 495 and 473 m/s; the vertical wavelength – 285 and 282 km; the horizontal wavelength – 1358 and 2322 km. The average values of these parameters for the medium-scale AGWs/TIDs in the subranges of 15–30 min (the average period being 22 min) and of 30–60 min (41 min) were respectively 0.13 and 0.13; 127 and 64 m/s; 289 and 268 m/s; 166 and 157 km; 403 and 658 km. It has been demonstrated that the largest number of TIDs is observed near the winter solstices and autumn equinoxes.Conclusions: As a result of a long-term systematic monitoring of the ionosphere state with the Kharkiv incoherent scatter radar, the characteristics of TIDs being observed in the periods close to equinoxes and solstices at low levels of solar and geomagnetic activities have been determined. The presence of largescale TIDs even under magnetically quiet conditions is proved. The plausible sources of the detected TIDs are discussed. The results obtained will improve the knowledge of the mid-latitude TIDs characteristics, as well as contribute to improvement of the global and regional models of the ionosphere.Key words: traveling ionospheric disturbances, magnetically quiet conditions, low solar activity, incoherent scatter radar, spectral and cross-correlation analysis, bandpass filtering, wave process characteristicsManuscript submitted  18.12.2019Radio phys. radio astron. 2020, 25(2): 100-117REFERENCES1. YIĞIT, E. and MEDVEDEV, A. S., 2015. Internal wave coupling processes in Earth’s atmosphere. Adv. Space Res. vol. 55, is. 4, pp. 983–1003. DOI: https://doi.org/10.1016/j.asr.2014.11.0202. HUNSUCKER, R. D., 1982. Atmospheric gravity waves generated in the high-latitude ionosphere: A review. Rev. Geophys. Space Phys. vol. 20, is. 2, pp. 293–315. DOI: https://doi.org/10.1029/RG020i002p002933. HOCKE, K. and SCHLEGEL, K., 1996. A review of atmospheric gravity waves and travelling ionospheric disturbances 1982–1995. Ann. Geophys. vol. 14, is. 9, pp. 917–940. DOI: https://doi.org/10.1007/s00585-996-0917-64. CHERNOGOR, L. F., PANASENKO, S. V., FROLOV, V. L. and DOMNIN, I. F., 2015. Observations of the Ionospheric Wave Disturbances Using the Kharkov Incoherent Scatter Radar upon RF Heating Near-Earth Plasma. Radiophys. Quantum Electron. vol. 58, is. 2, pp. 79–91. DOI: https://doi.org/10.1007/s11141-015-9583-45. GOSSARD, E. E. and HOOKE, W. H., 1978. Waves in the Atmosphere. Moscow, Russia: Mir Publ. (in Russian).6. MIYOSHI, Y., JIN, H., FUJIWARA, H. and SHINAGAWA, H., 2018. Numerical Study of Traveling Ionospheric Disturbances Generated by an Upward Propagating Gravity Wave. J. Geophys. Res. Space Phys. vol. 123, is. 3, pp. 2141–2155. DOI: https://doi.org/10.1002/2017JA0251107. TSUGAWA, T., SAITO, A. and OTSUKA, Y., 2004. A statistical study of large-scale traveling ionospheric disturbances using the GPS network in Japan. J. Geophys. Res. Space Phys. vol. 109, is. A6. DOI: https://doi.org/10.1029/2003JA0103028. DING, F., WAN, W., LIU, L., AFRAIMOVICH, E. L., VOEYKOV, S. V. and PEREVALOVA, N. P., 2008. A statistical study of large-scale traveling ionospheric disturbances observed by GPS TEC during major magnetic storms over the years 2003–2005. J. Geophys. Res. Space Phys. vol. 113, is. A3, id. A00A01. DOI: https://doi.org/10.1029/2008JA0130379. JONAH, O. F., COSTER, A., ZHANG, S., GONCHARENKO, L., ERICKSON, P. J., DE PAULA, E. R. and KHERANI, E. A., 2018. TID Observations and Source Analysis During the 2017 Memorial Day Weekend Geomagnetic Storm Over North America. J. Geophys. Res. Space Phys.  vol. 123, is. 10, pp. 8749–8765. DOI: https://doi.org/10.1029/2018JA02536710. ARRAS, C., WICKERT, J., BEYERLE, G., HEISE, S., SCHMIDT, T. and JACOB, C., 2008. A global climatology of ionospheric irregularities derived from GPS radio occultation. Geophys. Res. Lett. vol. 35, is. 14, id. L14809. DOI: https://doi.org/10.1029/2008GL03415811. OTSUKA, Y., SUZUKI, K., NAKAGAWA, S., NISHIOKA, M., SHIOKAWA, K. and TSUGAWA, T., 2013. GPS observations of medium‐scale traveling ionospheric disturbances over Europe. Ann. Geophys. vol. 31, is. 2, pp. 163–172. DOI:https://doi.org/10.5194/angeo-31-163-201312. MISYURA, V. A., PAKHOMOVA, O. V. and CHERNOGOR, L. F., 1989. Study of global and large-scale disturbances in the ionosphere using a network of ionosondes. Kosmicheskaya nauka s tekhnika. no. 4, pp. 72–75. (in Russian)13. MACDOUGALL, J. W. and JAYACHANDRAN, P. T., 2011. Solar terminator and auroral sources for traveling ionospheric disturbances in the midlatitude F region. J. Atmos. Sol.-Terr. Phys. vol. 73, is. 17-18, pp. 2437–2443. DOI: https://doi.org/10.1016/j.jastp.2011.10.00914. OTSUKA, Y., SHIOKAWA, K., OGAWA, T. and WILKINSON, P., 2004.  Geomagnetic conjugate observations of medium‐scale traveling ionospheric disturbances at midlatitude using all‐sky airglow imagers. Geophys. Res. Lett. vol. 31, is. 15, id. L15803. DOI: https://doi.org/10.1029/2004GL02026215. CHISHAM, G., LESTER. M., MILAN, S. E., FREEMAN, M. P., BRISTOW, W. A., GROCOTT, A., MCWILLIAMS, K. A., RUOHONIEMI, J. M., YEOMAN, T. K., DYSON, P. L., GREENWALD, R. A., KIKUCHI, T., PINNOCK, M., RASH, J. P. S., SATO, N., SOFKO, G. J., VILLAIN, J.-P. and WALKER, A. D. M., 2007. A decade of the Super Dual Auroral Radar Network (SuperDARN): scientific achievements, new techniques and future directions. Surv. Geophys. vol. 28, is. 1, pp. 33–109. DOI: https://doi.org/10.1007/s10712-007-9017-816. MEDVEDEV, A. V., RATOVSKY, K. G., TOLSTIKOV, M. V., SCHERBAKOV, A. A. and ALSATKIN, S. S., 2012. Statistical study of characteristics of propagation of travelling ionospheric disturbances from the data of ISTP SB RAS radiophysical complex. Solar-terrestrial physicsis. Novosibirsk: SB RAS Publ., is. 20, pp. 85–91. (in Russian)17. NICOLLS, M. J. and HEINSELMAN, C. J., 2007. Three‐dimensional measurements of traveling ionospheric disturbances with the Poker Flat Incoherent Scatter Radar. Geophys. Res. Lett. vol. 34, is. 21. id. L21104. DOI: https://doi.org/10.1029/2007GL03150618. NICOLLS, M. J., KELLEY, M. C., COSTER, A. J., GONZÁLEZ, S. A. and MAKELA, J. J. Imaging the structure of a large-scale TID using ISR and TEC data. Geophys. Res. Lett. 2004. vol. 31, is. 9, id. L09812. DOI: https://doi.org/10.1029/2004GL01979719. KLAUSNER, V., FAGUNDES, P. R., SAHAI, Y., WRASSE, C. M., PILLAT, V. G. and BECKER‐GUEDES, F., 2009. Observations of GW/TID oscillations in the F2 layer at low latitude during high and low solar activity, geomagnetic quiet and disturbed periods. J. Geophys. Res. Space Phys. vol. 114, is. A2, id. A02313. DOI: https://doi.org/10.1029/2008JA01344820. DOMNIN, I. F., CHEPURNYY, Y. M., EMELYANOV, L. Y., CHERNYAEV, S. V., KONONENKO, A. F., KOTOV, D. V., BOGOMAZ, O. V. and ISKRA, D. A., 2014. Kharkiv incoherent scatter facility. Bulletin of NTU “KhPI”. Series: Radiophysics and Ionosphere. Kharkiv: NTU “KhPI”, is. 47 (1089), pp. 28–42.21. BURMAKA, V. P., PANASENKO, S. V. and CHERNOGOR, L. F., 2007. Modern techniques for Spectral Analysis of Quasi-Periodic Variations in the Geospace Environment. Uspekhi Sovremennoi Radioelektroniki. is. 11, pp. 3–24. (in Russian).22. AKSONOVA, K. D. and PANASENKO, S. V., 2016. Seasonal variations in the parameters of wave processes in the ionosphere according to the method of incoherent scattering. Bulletin of NTU “KhPI”. Series: Radiophysics and Ionosphere. Kharkiv: NTU “KhPI”, is. 34 (1206), pp. 73–77. (in Russian).23. AKSONOVA, K. D. and PANASENKO, S. V., 2019. Manifestations of wave processes in ionospheric plasma parameters during the geospace storm on 1–3 September, 2016. Radio phys. radio astron. vol. 24, is. 1, pp. 55–67. DOI: https://doi.org/10.15407/rpra24.01.055 (in Russian)24. PANASENKO, S. V., 2015. Detection of wave disturbances of electron density in power variations of incoherent scatter signal. Bulletin of NTU “KhPI”. Series: Radiophysics and Ionosphere. Kharkiv: NTU “KhPI”, is. 37 (1146), pp. 13–17. (in Russian).25. VADAS, S. L. and NICOLLS, M. J., 2009. Temporal evolution of neutral, thermospheric winds and plasma response using PFISR measurements of gravity waves. J. Atmos. Sol.-Terr. Phys. vol. 71, is. 6-7, pp. 744–770. DOI: https://doi.org/10.1016/j.jastp.2009.01.01126. SOMSIKOV, V. M., 1991. Waves in the atmosphere caused by the solar terminator. A review. Geomagnetizm i Aeronomiya. vol. 31, is. 1, pp. 1–12. (in Russian).27. SONG, Q., DING, F., WAN, W., NING, B., LIU, L., ZHAO, B., LI, Q. and ZHANG, R., 2013. Statistical study of large-scale traveling ionospheric disturbances generated by the solar terminator over China. J. Geophys. Res. Space Phys. vol. 118, is. 7, pp. 4583–4593. DOI: https://doi.org/10.1002/jgra.5042328. AFRAIMOVICH, E. L., 2008. First GPS-TEC evidence for the wave structure excited by the solar terminator. Earth, Planets Space. vol. 60, pp. 895–900. DOI: https://doi.org/10.1186/BF0335284329. FORBES, J. M., BRUINSMA, S. L., MIYOSHI, Y. and FUJIWARA, H., 2008. A solar terminator wave in thermosphere neutral densities measured by the CHAMP satellite. Geophys. Res. Lett. vol. 35, is. 14, id. L14802. DOI: https://doi.org/10.1029/2008GL03407530. EROKHIN, N. S., ZOLNIKOVA, N. N. and MIKHAILOVSKAYA, L. A, 2007. Features of the interaction of internal gravitational waves with temperature-wind structures of the atmosphere during propagation into the ionosphere. Modern problems of Remote sensing of the Earth from Space. vol 4, is. 2, pp. 84–89. (in Russian).31. KUNITSYN, V. E., KRYSANOV, B. Y. and VORONTSOV, A. M., 2015. Acoustic-gravity waves in the Earth’s atmosphere generated by surface sources. Moscow Univ. Phys. vol. 70, is. 6, pp. 541–548. DOI: https://doi.org/10.3103/S002713491506012032. WALDOCK, J. A. and JONES, T. B., 1986. HF Doppler observations of medium-scale travelling ionospheric disturbances at mid-latitudes. J. Atmos. Terr. Phys. vol. 48, is. 3, pp. 245–260. DOI: https://doi.org/10.1016/0021-9169(86)90099-133. KSHEVETSKII, S. P. and KURDYAEVA, Y.A., 2016. The numerical study of impact of acoustic-gravity waves from a pressure source on the Earth’s surface on the thermosphere temperature. Transactions Kola Science Center. Heliogeophysics. series 2, pp. 161–166. (in Russian)34. VADAS, S. L. and LIU, H., 2009. Generation of large-scale gravity waves and neutral winds in the thermosphere from the dissipation of convectively generated gravity waves. J. Geophys. Res. Space Phys. vol. 114, is. A10. id. A10310. DOI: https://doi.org/10.1029/2009JA01410835. KOZAK, L. V. and PYLYPENKO, S. G., 2011. Temperature changes of the Earth upper atmosphere over storms from satellite measurements. Astronomical School’s Report. vol. 7, is. 1, pp. 42–47. DOI: https://doi.org/10.18372/2411-6602.07.104236. PANASENKO, S. V., GONCHARENKO, L. P., ERICKSON, P. J., AKSONOVA, K. D. and DOMNIN, I. F., 2018. Traveling ionospheric disturbances observed by Kharkiv and Millstone Hill incoherent scatter radars near vernal equinox and summer solstice. J. Atmos. Sol.-Terr. Phys. vol. 172, pp. 10–23. DOI: https://doi.org/10.1016/j.jastp.2018.03.00137. BRISTOW, W. A., GREENWALD, R. A. and VILLAIN, J. P., 1996. On the seasonal dependence of medium-scale atmospheric gravity waves in the upper atmosphere at high latitudes. J. Geophys. Res. Space Phys. vol. 101, is. A7, pp. 15685–15699. DOI: https://doi.org/10.1029/96JA0101038. ONISHCHENKO, O. G., POKHOTELOV, O. A. and ASTAFIEVA, N. M., 2007. Planetary waves in the atmosphere. Overview. Moscow, Russia: IKI RAN Publ. (in Russian).39. KOTAKE, N., OTSUKA, Y., TSUGAWA, T., OGAWA, T. and SAITO, A., 2006. Climatological study of GPS total electron content variations caused by medium‐scale traveling ionospheric disturbances. J. Geophys. Res. Space Phys. vol. 111, is. A4, id. A04306. DOI: https://doi.org/10.1029/2005JA01141840. PERKINS, F., 1973. Spread F and ionospheric currents. J. Geophys. Res. vol. 78, is. 1, pp. 218–226. DOI: https://doi.org/10.1029/JA078i001p00218

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