Abstract
Observational and theoretical studies have suggested gravity wave propagation and influences in the thermosphere and ionosphere for half a century. Gravity waves contribute, or are believed to contribute, to a variety of neutral and electrodynamic phenomena ranging from vertical coupling, energy and momentum transport and deposition, neutral perturbations and accelerations, traveling ionospheric disturbances, ionospheric irregularities, and plasma instabilities under quiet conditions to strong coupling from high to low latitudes and accompanying electrodynamics under storm-time conditions. Our goals here are to briefly review what has been learned to date, to illustrate some of the more recent results indicative of gravity wave effects, and to identify some aspects of neutral dynamics not previously considered that we expect may also have significant influences on neutral dynamics and electrodynamics in the thermosphere and ionosphere.
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References
Abdu MA, Kherani EA, Batista IS, de Paula ER, Fritts DC, Sobral JHA (2009) Gravity wave initiation of equatorial spread F/plasma bubble irregularities based on observational data from the SpreadFEx campaign. Ann Geophys (SpreadFEx special issue) 27:2607–2622
Bretherton FP (1969) Momentum transport by gravity waves. Quart J R Meteorol Soc 404:213–243
Chimonas G, Hauser HM, Bennett RD (1996) The excitation of ducted modes by passing internal waves. Phys Fluids (8):1486. doi:10.1063/1.868925
Danilov AD (1984) Direct and indirect estimates of turbulence around the turbopause. Adv Space Res 4(4):67–78
Djuth FT, Sulzer MP, Elder JH, Wickwar VB (1997) High-resolution studies of atmosphere-ionosphere coupling at Arecibo Observatory, Puerto Rico. Radio Sci 32:2321–2344
Djuth FT, Sulzer MP, Gonzales SA, Mathews JD, Elder JH, Walterscheid RL (2004) A continuum of gravity waves in the Arecibo thermosphere? Geophys Res Lett 31. doi:10.1029/2003GL019376
Drazin, PG (1977) On the instability of an internal gravity wave. Proc R Soc Lond 356:411–432
Earle GD, Musumba AM, Vadas SL (2008) Satellite-based measurements of gravity wave-induced midlatitude plasma density perturbations. J Geophys Res 113:A03303. doi:10.1029/2007JA012766
Einaudi F, Hines CO (1970) WKB approximation in application to acoustic-gravity waves. Can J Phys 48(12):1458–1471
Fritts DC, Abdu MA, Batista BR, Batista IS, Batista PP, Buriti R, Clemesha BR, Dautermann T, de Paula E, Fechine BJ, Fejer B, Gobbi D, Haase J, Kamalabadi F, Kherani EA, Laughman B, Lima PP, Liu H-L, Medeiros A, Pautet D, Sao Sabbas F, Sobral JHA, Stamus P, Takahashi H, Taylor MJ, Vadas SL, Vargas F, Wrasse C (2009a) Overview and summary of the Spread F Experiment (SpreadFEx). Ann Geophys 27:2141–2155
Fritts DC, Alexander MJ (2003) Gravity dynamics and effects in the middle atmosphere. Rev Geophys 41. doi:10.1029/2001RG000106
Fritts DC, Arendt S, Andreassen O (1998) Vorticity dynamics in a breaking internal gravity wave, 2. Vortex interactions and transition to turbulence. J Fluid Mech 367:47–65
Fritts DC, Dunkerton TJ (1984) A quasi-linear study of gravity wave saturation and self acceleration. J Atmos Sci 41:3272–3289
Fritts DC, Garten JF, Andreassen O (1996) Wave breaking and transition to turbulence in stratified shear flows. J Atmos Sci 53:1057–1085
Fritts DC, Isler JR, Andreassen O (1994) Gravity wave breaking in two and three dimensions, 2. Three-dimensional evolution and instability structure. J Geophys Res 99:8109–8123
Fritts DC, Vadas SL (2008) Gravity wave penetration into the thermosphere: sensitivity to solar cycle variations and mean winds. Ann Geophys (SpreadFEx special issue) 26:3841–3861
Fritts DC, Vadas SL, Riggin DM, Abdu MA, Batista IS, Takahashi H, Medeiros A, Kamalabadi F, Liu HL, Fejer BJ, Taylor MJ (2008) Gravity wave and tidal influences on equatorial spread F based on observations during the Spread F Experiment (SpreadFEx). Ann Geophys (SpreadFEx special issue) 26:3235–3252
Fritts DC, Vadas SA, Yamada Y (2002) An estimate of strong local gravity wave body forcing based on OH airglow and meteor radar observations. Geophys Res Lett 29(10). doi:10.1029/2001GL013753
Fritts DC, Wang L, Werne J, Lund T, Wan K (2009b) Gravity wave instability dynamics at high Reynolds numbers, 1: wave field evolution at large amplitudes and high frequencies. J Atmos Sci 66:1126–1148. doi:10.1175/2008JAS2726.1
Fritts DC, Wang L, Werne J, Lund T, Wan K (2009c) Gravity wave instability dynamics at high Reynolds numbers, 2: turbulence evolution, structure, and anisotropy. J Atmos Sci 66:1149–1171. doi:10.1175/2008JAS2727.1
Fuller-Rowell TJ, Codrescu MV, Moffett RJ, Quegan S (1994) Response of the thermosphere and ionosphere to geomagnetic storms. J Geophys Res 99(A3):3893–3914
Fuller-Rowell TJ, Millward GH, Richmond AD, Codrescu MV (2002) Storm-timechanges in the upper atmosphere at low latitudes. J Atmos Solar-Terr Phys 65:1383–1391
Grimshaw RHJ (1977) The modulation of an internal gravity wave packet and the resonance with the mean motion. Stud App Math 56:241–266
Hall CM, Manson AH, Meek CE (1998), Seasonal variation of the turbopause: One year of turbulence investigation at 69°N by the joint University of Tromsø/University of Saskatchewan MF radar. J Geophys Res 103(D22):28,769–28,773
Hasselmann K (1967) A criterion for non-linear wave stability. J Fluid Mech 30:737–739
Hickey MP, Cole KD (1987) A quartic dispersion relation for internal gravity waves in the thermosphere. J Atmos Solar-Terr Phys 49:889–899
Hickey MP, Cole KD (1988) A numerical model for gravity wave dissipation in the atmosphere. J Atmos Solar-Terr Phys 50(8):689–697
Hines CO (1960) Internal gravity waves at ionospheric heights. Can J Phys 38(11):1441–1481
Hines CO (1991) The saturation of gravity waves in the middle atmosphere. Part III: formation of the turbopause and of turbulent layers beneath it. J Atmos Sci 48(11):1380–1385
Hocke K, Schlegel K (1996) A review of atmospheric gravity waves and traveling ionospheric disturbances: 1982–1995. Ann Geophys 14:917–940
Hocke K, Tsuda T (2001) Gravity waves and ionospheric irregularities over tropical convection zones observed by GPS/MET radio occultation. Geophys Res Lett 28(14):2815–2818
Horinouchi T (2004) Simulated breaking of convectively generated mesoscale gravity waves and airglow modulation. J Atmos Solar-Terr Phys 66(6–9):755–767
Horinouchi T, Nakamura T, Kosaka J (2007) Convectively generated mesoscale gravity waves simulated throughout the middle atmosphere. Geophys Res Lett 29(21). doi:10.1029/2002GL016069
Huang CS, Kelley MC (1996) Nonlinear evolution of equatorial spread-F. 2. Gravity wave seeding of Rayleigh-Taylor instability J Geophys Res 101:293
Huang CS, Kelley MC, Hysell DL (1993) Nonlinear Rayleigh-Taylor instabilities, atmospheric gravity waves, and equatorial spread-F. J Geophys Res 98:15,631
Huang C, Zhang S, Yi F (2002) A numerical study of the nonlinear propagation of gravity-wave packets excited by temperature disturbance. Chi J Space Sci 22:330–338
Huang C, Zhang S, Yi F (2009) Gravity wave excitation through resonant interaction in a compressible atmosphere. Geophys Res Lett 36(1):L01803. doi:10.1029/2008GL035575
Hysell DL, Kelley MC, Swartz WE, Woodman RF (1990) Seeding and layering of equatorial spread-F. J Geophys Res 95:17,253
Innis JL, Conde M (2002) Characterization of acoustic–gravity waves in the upper thermosphere using dynamics explorer 2 wind and temperature spectrometer (WATS) and neutral atmosphere composition spectrometer (NACS) data. J Geophys Res 107(A12):1418. doi:10.1029/2002JA009370
Innis JL, Greet PA, Dyson PL (2001) Evidence for thermospheric gravity waves in the southern polar cap from ground-based vertical velocity and photometric observations. Ann Geophys 19:533–543
Jeong J, Hussain F (1995) On the identification of a vortex. J Fluid Mech 285:69–94
Kamalabadi F et al (2009) Electron densities in the lower thermosphere from GUVI 1356 tomographic inversions in support of SpreadFEx. Ann Geophys (SpreadFEx special issue) 27:2439–2448
Kherani EA, Abdu MA, de Paula ER, Fritts DC, Sobral JHA, de Meneses FC Jr (2009) The impact of gravity waves rising from convection in the lower atmosphere on the generation and nonlinear evolution of equatorial plasma bubbles. Ann Geophys (SpreadFEx special issue) 27:511–523
Kirchengast G, Hocke K, Schlegel K (1995), Gravity waves determined by modeling of traveling ionospheric disturbances in incoherent scatter radar measurements. Radio Sci 30(5):1551–1567
Klostermeyer J (1969) Gravity waves in the F-region. J Atmos Solar-Terr Phys 31(1):25–45. doi:10.1016/0021-9169(69)90079-8
Klostermeyer J (1972) Numerical calculation of gravity wave propagation in a realistic thermosphere. J Atmos Solar-Terr Phys 34(5):765–774. doi:10.1016/0021-9169(72)90109-2
Klostermeyer J (1978) Nonlinear investigation of the spatial resonance effect in the nighttime equatorial F region. J Geophys Res 83:3753–3760
Klostermeyer J (1991) Two-and three-dimensional parametric instabilities in finite amplitude internal gravity waves. Geophys Astrophys Fluid Dyn 61:1–25
Kudeki E, Akgiray A, Milla M, Chau JL, Hysell DL (2007) Equatorial spread-F initiation: post-sunset vortex, thermospheric winds, gravity waves. J Atmos Solar-Terr Phys 69:2416–2427
Lane TP, Reeder MJ, Clark TL (2001) Numerical modeling of gravity wave generation by deep tropical convection. J Atmos Sci 58(10):1249–1274
Lighthill MJ (1978) Waves in fluids. Cambridge University Press, Cambridge
Livneh DJ, Seker I, Djuth FT, Mathews JD (2007) Continuous quasiperiodic thermospheric waves over Arecibo. J Geophys Res 112:A07313. doi:10.1029/2006JA012225
Lombard, PN, Riley JJ (1996) On the breakdown into turbulence of propagating internal waves. Dyn Atmos Ocean 23:345–355
Lund T, Fritts DC (2011) Gravity wave breaking and turbulence generation in the thermosphere. Geophys Res Lett (to be submitted)
Luo Z, Fritts DC (1993) Gravity wave excitation by geostrophic adjustment of the jet stream, part ii: three-dimensional forcing. J Atmos Sci 50:104–115
Ma SY, Schlegel K, Xu JS (1998) Case studies of the propagation characteristics of auroral TIDS with EISCAT CP2 data using maximum entropy cross-spectral analysis. Ann Geophys 16(2):161–167. doi:10.1007/s00585-998-0161-3
Marks CJ, Eckermann SD (1995) A three-dimensional nonhydrostatic ray-tracing model for gravity waves: formulation and preliminary results for the middle atmosphere. J Atmos Sci 52(11):1959–1984
Mayr HG, Harris I, Herrero FA, Spencer NW, Varosil F, Pesnell WD (1990) Thermospheric gravity waves: observations and interpretation using the transfer function model (TFM). Space Sci Revs 54:297–375. doi:10.1007/BF00177800
McClure JP, Hanson WB, Hoffman JF (1977) Plasma bubble and irregularities in the equatorial ionosphere. J Geophys Res 82:2650
McClure JP, Singh S, Bamgboye DK, Johnson FS, Kil H (1998) Occurrence of equatorial F region irregularities: evidence for tropospheric seeding. J Geophys Res 103:29,119–29,135
McIntyre ME (1973) Mean motions and impulse of a guided internal gravity wave packet. J Fluid Mech 60:801–811
Mendillo M, Baumgardner J, Nottingham D, Aarons J, Reinisch B, Scali J, Kelley M (1997) Investigation of thermospheric-ionospheric dynamics with 6300-Å images from the Arecibo observatory. J Geophys Res 102(A4):7331–7343
Mied RR (1976) The occurrence of parametric instabilities in finite-amplitude internal gravity waves. J Fluid Mech 78:763–784
Nicolls MJ, Kelley MC, Coster AJ, Gonzalez SA, Makela JJ (2004) Imaging the structure of a large-scale TID using ISR and TEC data. Geophys Res Lett 31:L09812. doi:10.1029/2004GL019797
Oliver WL, Otsuka Y, Sato M, Takami T, Fukao S (1997) A climatology of F region gravity wave propagation over the middle and upper atmosphere radar. J Geophys Res 102:14,499–14,512
Ogawa T, Balan N, Otsuka Y, Shiokawa K, Ihara C, Shimomai T, Saito A (2002) Obervations and modeling of 630 nm airglow and total electron content associated with traveling ionospheric disturbances over Shigaraki, Japan. Earth Planets Space 54:45–56
Sentman DD, Wescott EM, Picard RH, Winick JR, Stenbaek-Nielson HC, Dewan EM, Moudry DR, São Sabbas FT, Heavner MJ (2003) Simultaneous observation of mesospheric gravity waves and sprites generated by a Midwestern thunderstorm. J Atmos Solar-Terr Phys 65:537–550
Shiokawa K et al (2002) A large-scale traveling ionospheric disturbance during the magnetic storm of 15 September 1999. J Geophys Res 107(A6):1088. doi:10.1029/2001JA000245
Sidi C, Teitelbaum H (1978) Thin shear turbulent layers within the lower thermosphere induced by non-linear interaction between tides and gravity waves. J Atmos Solar-Terr Phys 40(5):529–540. doi:10.1016/0021-9169(78)90090-9
Snively JB, Pasko VP (2008) Excitation of ducted gravity waves in the lower thermosphere by tropospheric sources. J Geophys Res 113:A06303. doi:10.1029/2007JA012693
Sonmor LJ, Klaassen GP (1997) Toward a unified theory of gravity wave stability. J Atmos Sci 54(22):2655–2680
Sutherland BR (1999) Propagation and reflection of large amplitude internal gravity waves. Phys Fluids 11:1081–1090
Sutherland BR (2000) Internal wave reflection in uniform shear. Quart J R Meteorol Soc 126(570):3255–3286
Sutherland BR (2001) Finite-amplitude internal wavepacket dispersion and breaking. J Fluid Mech 429:343–380
Sutherland BR (2006) Internal wave instability: wave-wave versus wave-induced mean flow interactions. Phys Fluids 18:074107. doi:10.1063/1.2219102
Vadas SL (2007) Horizontal and vertical propagation, and dissipation of gravity waves in the thermosphere from lower atmospheric and thermospheric sources. J Geophys Res 112:A06305. doi:10.1029/2006JA011845
Vadas SL, Fritts DC (2001) Gravity wave radiation and mean responses to local body forces in the atmosphere. J Atmos Sci 58:2249–2279
Vadas SL, Fritts DC (2002) The importance of spatial variability in the generation of secondary gravity waves from local body forces. Geophys Res Lett 29(20). doi: 10.1029/2002GL015574
Vadas SL, Fritts DC (2004) Thermospheric responses to gravity waves arising from mesoscale convective complexes. J Atmos Solar-Terr Phys 66:781–804
Vadas SL, Fritts DC (2005) Thermospheric responses to gravity waves: influences of increasing viscosity and thermal diffusivity. J Geophys Res 110:D15103. doi:10.1029/2004JD005574
Vadas SL, Fritts DC (2006) The influence of increasing temperature and solar variability on gravity wave structure and dissipation in the thermosphere. J Geophys Res (TIMED special issue) 111:A10812. doi:10.1029/2005JA011510
Vadas SL, Fritts DC (2009) Reconstruction of the gravity wave field from convective plumes via ray tracing. Ann Geophys (SpreadFEx special issue) 27(1):147–177
Vadas SL, Liu H-L (2009) Generation of large-scale gravity waves and neutral winds in the thermosphere from the dissipation of convectively generated gravity waves. J Geophys Res 114:A10310. doi:10.1029/2009JA014108
Vadas SL, Nicolls M (2008) Using PFISR measurements and gravity wave dissipative theory to determine the neutral, background thermospheric winds. Geophys Res Lett 35:L02105. doi:10.1029/2007GL031522
Vadas SL, Nicolls M (2009) Temporal evolution of neutral, thermospheric winds and plasma response using PFISR measurements of gravity waves. J Atmos Solar-Terr Phys 71:740–770
Vadas SL, Taylor MJ, Pautet P-D, Stamus P, Fritts DC, Liu H-L, Sao Sabbas F, Rampinelli VT, Batista P, Takahashi H (2009) Convection: the likely source of the medium-scale gravity waves observed in the OH airglow layer near Brasilia, Brazil, during the SpreadFEx campaign. Ann Geophys (SpreadFEx special issue) 27:231–259
Walterscheid RL, Schubert G (1990) Nonlinear evolution of an upward propagating gravity wave: overturning, convection, transience and turbulence. J Atmos Sci 47:101–125
Whitham GB (1965) A general approach to linear and nonlinear dispersive waves using a Lagrangian. J Fluid Mech 22:273–283
Whitham GB (1974) Linear and nonlinear waves. Wiley, New York, NY
Yamada Y, Fukunishi H, Nakamura T, Tsuda T (2001) Breakdown of small-scale quasi-stationary gravity wave and transition to turbulence observed in OH airglow. Geophys Res Lett 28:2153–2156
Yeh KC, Liu CH (1981) The instability of atmospheric gravity waves through wave-wave interactions. J Geophys Res 86(C10):9722–9728
Yue J, Vadas SL, She C-Y, Nakamura T, Reising S, Krueger D, Liu H-Li, Stamus P, Thorsen D, Lyons W, Li T (2009) A study of OH imager observed concentric gravity waves near Fort Collins on 11 May 2004. J Geophys Res 114:D06104. doi:10.1029/2008JD011244
Acknowledgments
Preparation of this paper was supported by AFOSR contract FA9550-09-C-0197, NASA contract NNH09CF40C, and NSF grant ATM-0836407. We also acknowledge the DoD High Performance Computing Modernization Office for computational resources employed for the simulations described.
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Fritts, D.C., Lund, T.S. (2011). Gravity Wave Influences in the Thermosphere and Ionosphere: Observations and Recent Modeling. In: Abdu, M., Pancheva, D. (eds) Aeronomy of the Earth's Atmosphere and Ionosphere. IAGA Special Sopron Book Series, vol 2. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-0326-1_8
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