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References

  • Cheng, Z., and S. A. Cummer (2002), Multi-path D region ionosphere remote sensing, paper presented at NSF CEDAR Workshop, Natl. Sci. Found., Longmont, Colo.
  • Cipriano, J. P., L. C. Hale, and J. D. Mitchell (1974), Relations among low ionospheric parameters and A3 radio wave absorption, J. Geophys. Res., 79, 22602265.
  • Cole, R. K.Jr. (1965), The Schumann resonances, J. Res. Natl. Bur. Stand. U.S., Sect. D, 69, 13451349.
  • Cole, R. K., and E. T. Pierce (1965), Electrification in the Earth's atmosphere for altitude between 0 and 100 km, J. Geophys. Res, 70, 27352749.
  • Cummer, S. A. (1997), Lightning and ionospheric remote sensing using VLF/ELF radio atmospherics, Ph.D. thesis, Dep. of Electr. Eng., Stanford Univ., Stanford, Calif.
  • Cummer, S. A., U. S. Inan, and T. F. Bell (1998), Ionospheric D-region remote sensing using VLF radio atmospherics, Radio Sci., 33, 17811792.
  • Danilov, A. D. (1970), Chemistry of the Ionosphere, Springer, New York.
  • Galejs, J. (1962), A further note on terrestrial extremely low frequency propagation in the presence of an isotropic ionosphere with an exponential conductivity-height profile, J. Geophys. Res., 67, 27152728.
  • Greifinger, C., and P. Greifinger (1978), Approximate method for determining ELF eigenvalues in the Earth-ionosphere waveguide, Radio Sci., 13, 831837.
  • Greifinger, C., and P. Greifinger (1979), On the ionospheric parameters which govern high-latitude ELF propagation in the Earth-ionosphere waveguide, Radio Sci., 14, 889895.
  • Greifinger, C., and P. Greifinger (1986), Noniterative procedure for calculating ELF mode constants in the anisotropic Earth-ionosphere waveguide, Radio Sci., 21, 981990.
  • Greifinger, P., V. Mushtak, and E. Williams (2005), The lower characteristic ELF altitude of the Earth-ionosphere waveguide: Schumann resonance observations and aeronomical estimates, paper presented at 6th International Symposium on Electromagnetic Compatibility and Electromagnetic Ecology, Inst. of Electr. and Electron. Eng. St. Petersburg, Russia.
  • Gringel, W., J. M. Rosen, and D. J. Hofmann (1986), Electrical structure from 0 to 30 kilometers, in The Earth's Electrical Environment, pp. 166182, Natl. Acad. Press, Washington, D. C.
  • Gupta, S. (1998), Diurnal and seasonal variation of D-region electron density at low latitude, Adv. Space Res., 21, 875881.
  • Hale, L. C. (1974), Positive ions in the mesosphere, in Methods of Measurements and Results of Lower Ionospheric Structure, edited by K. Rawer, pp. 219235, Akademie, Berlin.
  • Hargreaves, J. K. (1992), The Solar-Terrestrial Environment, Cambridge Atmos. Space Sci. Ser., vol. 5, Cambridge Univ. Press, New York.
  • Heliospheric Physics Laboratory, (2001), International Reference Ionosphere, IRI-2001, http://nssdc.gsfc.nasa.gov/space/model/models/iri.html, Natl. Space Sci. Data Cent., Goddard Space Flight Cent., Greenbelt, Md.
  • Holzworth, R. H., M. C. Kelley, C. L. Siefring, L. C. Hale, and J. D. Mitchell (1985), Electrical measurements in the atmosphere and the ionosphere over an active thunderstorm: 2. Direct current electric fields and conductivity, J. Geophys. Res., 90, 98249830.
  • Jones, D. L. (1967), Schumann resonances and E. L. F. propagation for inhomogeneous, isotropic ionosphere profiles, J. Atmos. Terr. Phys., 29, 10371044.
  • Kirillov, V. V. (1993), Parameters of the Earth-ionosphere waveguide at extremely low frequencies (in Russian), in The Problems of Diffraction and Wave Propagation, vol. 25, pp. 3552, St. Petersburg State Univ., St. Petersburg, Russia.
  • Kirillov, V. V., and V. N. Kopeykin (2002), Solving a two-dimensional telegraph equation with anisotropic parameter, Radiophys. Quantum Electron., 45, 929941.
  • Kirillov, V. V., and V. N. Kopeykin (2003), Formation of a resonance structure of the local inductance of the ionosphere at frequencies 0.1–10 Hz, Radiophys. Quantum Electron., 46, 112.
  • Kirillov, V. V., V. N. Kopeykin, and V. C. Mushtak (1997), ELF electromagnetic waves within the Earth-ionosphere waveguide (in Russian), Geomagn. Aeron., 37, 114120.
  • Madden, T., and W. Thompson (1965), Low frequency electromagnetic oscillations of the Earth-ionosphere cavity, Rev. Geophys., 3, 211254.
  • Mission Research Corporation (2000), Satellite and ground based data exploitation for NUDET discrimination: Characterizing atmospheric and electrodynamic emissions from lightning, sprites, jets and elves, Final Rep. on Contract DE-AC04-98AL79469, chap. 8, pp. 143186, Nashua, N. H.
  • Mushtak, V. C., and E. R. Williams (2002), ELF propagation parameters for uniform models of the Earth-ionosphere waveguide, J. Atmos. Sol. Terr. Phys., 64, 19892001.
  • Mushtak, V., R. Boldi, S. Heckman, E. Huang, and E. Williams (1998), Interpretation of ELF observations (West Greenwich, Rhode Island) on the basis of an asymmetrical model of the Earth-ionosphere wave-guide: the Dawn/dusk effect and apparent bearings of African transients, paper presented at Schumann Resonance Symposium and Workshop, U.S.-Hung. Sci. and Technol. Joint Fund, Sopron, Hungary.
  • Mushtak, V., R. Boldi, and E. Williams (1999), Schumann resonances and the temporal-spatial dynamics of global thunderstorm activity, paper presented at XI International Conference on Atmospheric Electricity, NASA, Guntersville, Ala.
  • Mushtak, V., C. Price, and E. Williams (2002), The physical principles of the combined ELF/VLF method for single-station global location of lightning, paper presented at World Space Congress, Comm. on Space Res., Houston, Tex.
  • Nickolaenko, A. P., and M. Hayakawa (2002), Resonances in the Earth-Ionosphere Cavity, Springer, New York.
  • Pasko, V. P., U. S. Inan, T. F. Bell, and Y. N. Taranenko (1997), Sprites produced by quasi-electrostatic heating and ionization in the lower ionosphere, J. Geophys. Res., 102, 45294561.
  • Price, C., and V. Mushtak (2001), The impact of the August 17, 1998 gamma ray burst on the Schumann resonance, J. Atmos. Sol. Terr. Phys., 10431047.
  • Reid, G. C. (1986), Electrical structure of the middle atmosphere, in The Earth's Electrical Environment, pp. 183194, Natl. Acad. Press, Washington, D. C.
  • Sátori, G., E. Williams, and V. Mushtak (2005), Response of the Earth-ionosphere cavity resonator to the 11-year solar cycle in X-radiation, J. Atmos. Sol. Terr. Phys., 67, 553562.
  • Sentman, D. D. (1990), Approximate Schumann resonance parameters for a two-scale-height ionosphere, J. Atmos. Terr. Phys., 52, 3546.
  • Swider, W. (1988), Ionic mobility, mean mass, and conductivity in the middle atmosphere from near ground level to 70 km, Radio Sci., 23, 389399.
  • Wait, J. R. (1964), On the theory of Schumann resonances in the Earth-ionosphere cavity, Can. J. Phys., 42, 575582.
  • Williams, E. R., V. C. Mushtak, and A. P. Nickolaenko (2006), Distinguishing ionospheric models using Schumann resonance spectra, J. Geophys. Res., 111, D16107, doi:10.1029/2005JD006944.
  • Zadorozhny, A. M., and A. A. Tyutin (1998), Effects of geomagnetic activity on the mesospheric electric fields, Ann. Geophys., 16, 15441551.