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Influence of Tropical Cyclones on the Ionosphere: A Study of the Strongest Hurricanes in the Last 10 Years

This research paper analyzes the impact of the strongest hurricanes on coastal populations and investigates the dependencies between ionospheric and atmospheric parameters during tropical cyclones, aiming for prediction purposes.

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Influence of Tropical Cyclones on the Ionosphere: A Study of the Strongest Hurricanes in the Last 10 Years

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  1. The landing hurricanes influence to ionosphere Space Research Institute, Moscow, Russia,L.B.Vanina-Dart (vandart@seeingear.org)Tropical cyclones (TCs) are the “ocean–atmosphere” system natural instability events. The landing TCs are mostly dangerous for people. In this paper author analyzed the strongest well-known hurricanes, which damaged coast populations of different countries for the last 10 years. In the base of this paper author put search of dependencies between the ionospheric and atmospheric parameters ( from satellite and ground both ) during TC action in prediction purpose.

  2. It is known that the whole spectrum of powerful dynamical phenomena is originated in the tropical zone of the atmosphere. The most intense of these phenomena are TCs, which are possible potential sources of the influence from “below”. Catastrophic atmospheric vortices, which originate near the equator, and develop in the tropical zone of the Earth’s atmosphere, present a peculiar mechanism of effective heat effluence under such atmospheric conditions, when the action of ordinary mechanisms (the main mechanisms are turbulent convection and global circulation) becomes evidently insufficient. Thus, the catastrophic atmospheric vortex systems play an important (and possibly determining) role in the formation of the temperature regime of the Earth(the greenhouse effect), removing excess heat and preventing from strong overheating of the atmosphere (of its tropical part) and the surface ocean layer in the tropical zone.

  3. “Being a product of ionization of various neutral gas components, the Earth’s ionosphere rapidly enough (for example, at heights of the Е layer, the characteristic time of a reaction to changes in the ionization rate by auroral discrete type electrons is a few seconds) reacts to changes in space radiation and also in the composition of the neutral atmosphere.”L.B. Vanina-Dart, A.A. Romanov, E.A. Sharkov, Influence of a tropical cyclone on the upper ionosphere according to tomography sounding data over Sakhalin Island in November 2007// 2011, Geomagnetism and Aeronomy,December 2011, Volume 51,Issue 6, p. 774-782

  4. There are some possible ways of TC-ionosphere interactions: 1. TCs would affect conditions in the ionosphere through both the atmospheric GWs from their strong convective towers and the associated synoptic-scale motions in the stratosphere and ionosphere. (G.J.Bell,1981). 2. An effect of external electric currents on the global atmosphere-ionosphere el. circuit may be one of possible mechanisms of interaction between atmospheric and ionospheric components. External currents with a horizontal scale of about one hundred of kms may be related to the vertical large - scale convection of the cloudy atmosphere in the zone of a TC and to the charge separation in this region. The electric field disturbance arises due to perturbation in the atmosphere – ionosphere electric circuit generated by the upward transport of charged water drops and aerosols in TC convection zone (Isaev et al, 2006). 3.GWs generated at tropospheric altitudes propagate to the F-region. GWs generated from storms break near 100 km and produce secondary waves that continue to propagate upward GWs modulate the E-region plasma producing polarization fields that map to F-region altitudes. Strong convection cells produce a wide spectrum of GWs. GWs increase in amplitude with increasing altitude and may become unstable. Only waves propagating at the certain angles and with the correct amplitude can reach thermospheric altitudes. Once in the thermosphere, only those waves oriented to the magnetic field in a particular manner may produce ionospheric disturbances (dr.Rebecca Bishop, PSL/SSAL, 30 March 2012)

  5. Effects of typhoon Matsa on ionospheric TEC.Tian Mao, JingSong Wang, GuangLin Yang, Tao Yu, JinSong Ping, YuCheng SuoChinese Science Bulletin March 2010, Volume 55, Issue 8, pp 712-717 Date: 29 Aug 2009 “The effects of typhoon Matsa on the ionosphere are studied by using GPS-TEC data observed at about 50 GPS stations. It is shown that the ionosphere has already influenced and TEC tends to increase before the landing of Matsa, and the difference of TEC from its monthly median over the typhoon area is about 5 TECU.With the landing of Matsa, both the magnitude and the area of increased TEC decrease. One day after the landing of Matsa, TEC reaches its minimum and is lower than the monthly median. In comparison of TEC along the typhoon’s path with that along three reference paths far from the typhoon, it is found that typhoon’s impact on TEC can be fully distinguished. The evolution of TEC variation has the same tendency as reported typhoon-induced foF2.”

  6. The strongest well-known hurricanes, which damaged coast populations of different countries for the last 10 years (W.Pacific).Year Name Date Wind Cat 2002 Typhoon RUSA 22 AUG-01 SEP 115 4 2003 Super Typhoon MAEMI 05-13 SEP 150 5 2003 Super Typhoon IMBUDO 16-24 JUL 130 42004 Super Typhoon TOKAGE 12-20 OCT 120 52004 Typhoon RANANIM 07-13 AUG 90 22005 Super Typhoon HAITANG 11-19 JUL 140 5 2006 Super Typhoon SAOMAI 04-10 AUG 140 5…... Typhoon Morakot in August 2009 The typhoon triggered record rainfall in Taiwan – resulting in widespread damage, flooding and mudslides, with the estimated loss of more than 600 lives. This summer, the country was more prepared when Typhoon Nanmadol hit Taiwan: 8,000 were instantly evacuated and 22,000 military personnel were on standby. Super Typhoon Haiyan, one of the most powerful storms ever recorded on Earth, struck the Philippines Nov. 8, 2013, it tore a wide swath of destruction across large parts of the island nation.

  7. 2010–11 Australian region cyclone season Season summary map First system formed 28 October 2010 Last system dissipated 20 April 2011 Strongest storm Yasi – 929 hPa (mbar), 205 km/h (125 mph) (10-minute sustained) Tropical lows 28 Tropical cyclones 10 Severe tropical cyclones 5 Total fatalities 3 total Total damage $3.64 billion (2011 USD)

  8. Strongest storm Yasi – 929hPa (mbar), 205 km/h -19.70S, 146.90E - 27.50S, 152.90E - 34 0S, 150.70E

  9. 01/12 01/19 02/06 02/08 02/09 02/14 02/15 02/17 02/18 02/19 02/20 02/21 03/05 03/06

  10. 2013–14 Australian region cyclone season Season summary map First system formed 20 November 2013 Last system dissipated 5 May 2014 Strongest storm Ita – 930 hPa (mbar), 215 km/h (130 mph) (10-minute sustained) Tropical lows 24 Tropical cyclones 10 Severe tropical cyclones 5 Total fatalities 22 total Total damage $957.8 million (2014 USD)

  11. Strongest storm Ita– 930 hPa (mbar), 215 km/h MTSAT Wind Shear (kts) →

  12. -270S, 1530E

  13. Data F10.7 2014-04-01-153 2014-04-02-155 2014-04-03-153 2014-04-04-157 2014-04-05-142 2014-04-06-141 2014-04-07-140 2014-04-08-132 2014-04-09-131 2014-04-10-137 2014-04-11-138 2014-04-12-137 2014-04-13-138 2014-04-14-151 2014-04-15-163 2014-04-16-185 -12.50S, • 1310E 2014-04-16-185 2014-04-17-180 2014-04-18-174 2014-04-19-171 2014-04-20-164 2014-04-21-160 2014-04-22-146 2014-04-23-138 2014-04-24-132 2014-04-25-126 2014-04-26-122 2014-04-27-120 2014-04-28-123 2014-04-29-122 2014-04-30-126 -19.70S, • 146.90E -27.50S, • 152.90E

  14. Relationships between meteorological and ionospheric phenomena come about through vertical motions in the ionosphere induced by underlying large scale weather systems or from gravity waves which originate from the surface or upper troposphere. The amplitude of gravity waves (GWs) of certain frequencies increases exponentially a with height because of the decreasing density. The growth factor is given, if by the square root of the ratio of the atmospheric density at source and at the height of interest. A displacement at the earth's surface of a few centimeters can originate an atmospheric GW which will grow in amplitude to several kilometers at ionospheric levels. Growth factors of 104 to 105are typical. The layers of constant electron density move up and down with oscillatory motions similar to the acoustic pressure wave itself.

  15. Conclusion“Relationships between meteorological and ionospheric phenomena come about through vertical motions in the ionosphere induced by underlying large scale weather systems or from gravity waves which originate from the surface or upper troposphere. “

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