doi:10.1007/s00376-016-5285-x

Abdullah A. J., 1966: The spiral bands of a Hurricane: A possible dynamic explanation. J. Atmos. Sci., 23, 367- 375.10.1175/1520-0469(1966)0232.0.CO;2

f354c4f0feee36209d1eb76dc9b459e0

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1966JAtS...23..367A

http://adsabs.harvard.edu/abs/1966JAtS...23..367AIn this paper an attempt is made to explain the shape and behavior of the spiral bands of a hurricane. The main hypothesis is that the bands are associated with gravitational waves of finite amplitude propagating at. the interface of a high-level inversion. An external source of disturbance is postulated in the form of a fresh surge of air at the exterior region of the hurricane. It is shown that this mechanism leads to the formation of bands of the required shape. The spiral bands are therefore related to the squall lines of temperate latitudes. Two numerical examples are worked out to illustrate the proposed mechanism.

Alexand er, M. J., R. A. Vincent, 2000: Gravity waves in the tropical lower stratosphere: A model study of seasonal and interannual variability. J. Geophys. Res.,105, 17 983-17 993, doi: 10.1029/2000JD900197.10.1029/2000JD900197

7747f525b8d6ed9ed9ee9b22d528f3a5

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2000JD900197%2Fcitedby

http://onlinelibrary.wiley.com/doi/10.1029/2000JD900197/citedbyA model study is presented to clarify the relationship between gravity-wave properties observed in the stratosphere and the sources for the waves, presumed to be in the troposphere. The observations are balloon-borne radiosondes launched from Cocos Island in the tropical Indian Ocean (12°S, 97°E), and the analysis of these data is described in a companion paper [Vincent and Alexander, this issue]. The dominant time variations in the observed gravity wave activity are annual and quasi-biennial patterns in the zonal momentum flux and kinetic energy density. The background zonal winds at this site vary with the same periods, and these are known to be capable of causing dramatic variations in the observable properties of the waves even if the sources for the waves are constant in time. The results presented here clarify (1) the nature of the sources for the gravity waves observed in the stratosphere, (2) the limitations of the observations for observing the full range of gravity wave perturbations potentially present in the atmosphere, and (3) the role the observed waves can play in forcing the quasibiennial oscillation (QBO) in the zonal winds at this latitude. The stratospheric waves appear to originate near the height of the tropopause, so the source is apparently related to deep convection. No seasonal or interannual variations in the convection need be assumed to understand the observations. The waves at the tropopause appear to have a phase speed distribution that is narrowly confined near zero phase speed relative to the ground. The source is likely related to slowly propagating tropospheric convection and the wind near the tropopause. Variations observed in the stratospheric data are caused by both the wind shear in the stratosphere and the ability of waves with these characteristics to propagate vertically without severe dissipation. Higher phase speed waves may be present and could carry significant momentum flux vertically into the stratosphere and mesosphere but would be extremely difficult to see in these radiosonde data. The observed waves can contribute substantially to the descent of the eastward shear zones characteristic of the "westerly" phase of the QBO in the lower stratosphere zonal winds.

Alexand er, M. J., J. R. Holton, D. R. Durran, 1995: The gravity wave response above deep convection in a squall line simulation. J. Atmos. Sci., 52, 2212- 2226.ea82da58c8c7307676ec3e1da5001872

http%3A%2F%2Fadsabs.harvard.edu%2Fcgi-bin%2Fnph-data_query%3Fbibcode%3D1995JAtS...52.2212A%26db_key%3DPHY%26link_type%3DEJOURNAL

/s?wd=paperuri%3A%2863089e3f8989c41e971882125d31c65c%29&filter=sc_long_sign&tn=SE_xueshusource_2kduw22v&sc_vurl=http%3A%2F%2Fadsabs.harvard.edu%2Fcgi-bin%2Fnph-data_query%3Fbibcode%3D1995JAtS...52.2212A%26db_key%3DPHY%26link_type%3DEJOURNAL&ie=utf-8&sc_us=2835723802350446501

Allen S. J., R. A. Vincent, 1995: Gravity wave activity in the lower atmosphere: Seasonal and latitudinal variations. J. Geophys. Res., 100, 1327- 1350.10.1029/94JD02688

3b6153b8fa874cd090fcef21b5ffe395

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F94JD02688%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/94JD02688/fullA climatology of gravity wave activity in the lower atmosphere based on high-resolution radiosonde measurements provided by the Australian Bureau of Meteorology is presented. These data are ideal for investigating gravity wave activity and its variation with position and time. Observations from 18 meteorological stations within Australia and Antarctica, covering a latitude range of 12 deg S - 68 deg S and a longitude range of 78 deg E - 159 E, are discussed. Vertical wavenumber power spectra of normalized temperature fluctuations are calculated within both the troposphere and the lower stratosphere and are compared with the predictions of current gravity wave saturation theories. Estimates of important model parameters such as the total gravity wave energy per unit mass are also presented. The vertical wavenumber power spectra are found to remain approximately invariant with time and geographic location with only one significant exception. Spectral amplitudes observed within the lower stratosphere are found to be consistent with theoretical expectations but the amplitudes observed within the troposphere are consistently larger than expected, often by as much as a factor of about 3. Seasonal variations of stratospheric wave energy per unit mass are identified with maxima occurring during the low-latitude wet season and during the midlatitude winter. These variations do not exceed a factor of about 2. Similar variations are not found in the troposphere where temperature fluctuations are likely to be contaminated by convection and inversions. The largest values of wave energy density are typically found near the tropopause.

Arunachalam Srinivasan, M., S. V. B. Rao, R. Suresh, 2014: Investigation of convectively generated gravity wave characteristics and generation mechanisms during the passage of thunderstorm and squall line over Gadanki (13.5^\circN,79.2^\circE). Annales Geophysicae, 32, 57-68, doi: 10.5194/angeo-32-57-2014.10.5194/angeo-32-57-2014

a0ad6b014a3583bbfef503661649d577

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F2014AnGeo..32...57A

http://adsabs.harvard.edu/abs/2014AnGeo..32...57AThis study illustrates the convectively generated gravity wave generation mechanisms during the passage of thunderstorms and squall line using Indian MST radar. For the first time, it has been shown that all three generation mechanisms have been involved in the generation of gravity waves during the passage of squall line event. It is observed that the periodicities in the range of 8-80 min in the tropospheric and 8-32 min in the lower stratospheric regions and vertical wavelengths in the range of 3.2-4.8 km in the tropospheric and 1.2-1.92 km in the lower stratospheric regions are found to be dominant in the present study and are distinctly different during initial, mature and dissipative phases of convection. Amplitude of vertical wind has been weakened (from ~ 4-6 m sto ~ 1 m s) considerably after 10-30 min of a convection event. It appears that the wind shear associated with the convective clouds acted like an obstacle to the mean background flow during the squall line passage generated gravity waves. The phase profiles corresponding to the dominant period show both downward and upward propagation of waves. The vertical extent of heating is found to be deeper during squall line event compared with thunderstorm event. From the phase profiles, during 27 September 2004, two peaks of constant phase region are observed. One is due to convective elements and the other is due to strong background wind shear; however, only one peak is observed on 29 September 2004, which is only due to convective processes.

Chane-Ming F., Z. Chen, and F. Roux, 2010: Analysis of gravity-waves produced by intense tropical cyclones. Annales Geophysicae,28, 531-547, doi: 10.5194/angeo-28-531-2010.10.5194/angeo-28-531-2010

d81c21d200d87ef56da3db5d282593ce

http%3A%2F%2Fonlinelibrary.wiley.com%2Fresolve%2Freference%2FXREF%3Fid%3D10.5194%2Fangeo-28-531-2010

http://onlinelibrary.wiley.com/resolve/reference/XREF?id=10.5194/angeo-28-531-2010Conventional and wavelet methods are combined to characterize gravity-waves (GWs) produced by two intense tropical cyclones (TCs) in the upper troposphere and lower stratosphere (UT/LS) from GPS winsonde data. Analyses reveal large contribution of GWs induced by TCs to wave energy densities in the UT/LS. An increase in total energy density of about 30% of the climatological energy density in austral summer was estimated in the LS above Tromelin during TC Dina. Four distinct periods in GW activity in relation with TC Faxai stages is observed in the UT. Globally, GWs have periods of 6 h–2.5 days, vertical wavelenghts of 1–3 km and horizontal wavelengths <1000 km in the UT during the evolution of TCs. Horizontal wavelengths are longer in the LS and about 2200 km during TCs. Convective activity over the basin and GW energy density were modulated by mixed equatorial waves of 3–4 days, 6–8 days and 10–13 days confirmed by H vm ller diagram, Fourier and wavelet analyses of OLR data. Moreover, location of GW sources is below the tropopause height when TCs are intense otherwise varies at lower tropospheric heights depending on the strength of convection. Finally, the maximum surface wind speeds of TCs Dina and Faxai can be linearly estimated with total energy densities.

Chen S. M., Y. Y. Lu, W. B. Li, and Z. P. Wen, 2015: Identification and analysis of high-frequency oscillations in the eyewalls of tropical cyclones. Adv. Atmos. Sci.,32(6), 624-634, doi: 10.1007/s00376-014-4063-x.10.1007/s00376-014-4063-x

d9c02cd7765812d486446e5d62988b39

http%3A%2F%2Flink.springer.com%2Farticle%2F10.1007%2Fs00376-014-4063-x

http://d.wanfangdata.com.cn/Periodical_dqkxjz-e201505005.aspxHigh-frequency oscillations, with periods of about 2 hours, are first identified by applying wavelet analysis to observed minutely wind speeds around the eye and eyewall of tropical cyclones (TCs). Analysis of a model simulation of Typhoon Hagupit (2008) shows that the oscillations also occur in the TC intensity, vertical motion, convergence activity and air density around the eyewall. Sequences of oscillations in these variables follow a certain order.

Cho J. Y. N., 1995: Inertio-gravity wave parameter estimation from cross-spectral analysis. J. Geophys. Res.,100(D9), 18 727-18 737, doi: 10.1029/95JD01752.10.1029/95JD01752

1bc765834c932ac1ae3c6643cd864c87

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F95JD01752%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/95JD01752/fullWe outline a method for extracting inertio-gravity wave parameters using the autospectra and cross spectra of the horizontal perturbation winds. In essence, we define a statistical hodograph for each spectral bin, thus combining the advantages of the rotary spectrum and hodograph methods. Furthermore, we include the effects of the background vertical shear in the parameter estimation equations, a step that had often been omitted in the past. Applying this technique to a long-period data set taken with the Arecibo 430-MHz radar, we explore its usefulness as well as its limitations. Our analysis of this data set also supports the interpretation of horizontal wind-perturbation rotation in the lower stratosphere over Arecibo as inertio-gravity waves rather than mountain waves imbedded within a background vertical shear.

Clark T. L., T. Hauf, and J. P. Kuettner, 1986: Convectively forced internal gravity waves: Results from two-dimensional numerical experiments. Quart. J. Roy. Meteor. Soc., 112, 899- 925.10.1002/qj.49711247402

324bb6fb-7166-4590-a5ac-97bdd69144c0

8984fa02b0b9497c8327cc04880f2ccb

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1002%2Fqj.49711247402%2Fabstract

refpaperuri:(90c3570f836e2fc8fb10366d22f0f46c)

http://onlinelibrary.wiley.com/doi/10.1002/qj.49711247402/abstractAbstract Two-dimensional numerical simulations were performed to investigate the nature of tropospheric internal gravity waves of the type which are observed to occur above active thermal convection over an unstable boundary layer. These gravity waves are believed to be excited by a combination of pure thermal forcing and by the boundary layer eddies and cumulus clouds acting as obstacles to the flow in the presence of mean environmental wind shear. Large amplitude internal gravity waves were obtained in the simulations with amplitudes and horizontal scales similar to the 12 June 1984 aircraft observations over western Nebraska. This was a day with strong wind shear in the lowest 3 km above the ground and with scattered cumulus clouds topping the boundary layer. The simulations show that there is significant difference between the early time solutions (as might be predicted by linear theory) and late time solutions for the boundary layer eddy structure. A layer interaction occurs in which gravity waves of the stable layer are excited by the boundary layer convection. There is evidence to suggest that this layer interaction occurs both with and without shear but that it is stronger in the presence of low-level shear. Results indicate that shear (or the obstacle) effect is a more efficient generator of gravity waves than is the pure thermal forcing. The simulations show that the gravity waves initially forced by the boundary layer eddies lead to a feedback mechanism that acts to organize the boundary layer eddies and the cumulus convection. The solutions suggest that the character of fair weather convection (moist or dry) is a non-local problem involving at times the full depth of the troposphere. The clouds produced in the simulations have very little influence on the wave field or boundary layer eddy structure as they are relatively small cumuli. On the other hand the clouds are strongly influenced by the interactions between the wave and eddy fields. Upshear growth of cumulus clouds similar to that which is frequently observed in nature is reproduced in the simulations. The development of feeder (-榝eeder- is used here in a dynamical sense only) clouds on (typically) the upshear side of the cloud is found to be a result of the interaction between the gravity wave field and the dry and moist convection. The relative phase velocity between the gravity waves and the cloud plays a crucial role in determining the character of the cumulus cloud growth in the present simulations. These simulations suggest that the dynamics both internal and external to the boundary of a cumulus cloud is a complicated mix between wave dynamics and the usually considered convection dynamics. A brief discussion of the implications of the present results to cloud boundary baroclinic instability dynamics is also presented.

Das S. S., K. K. Kumar, and K. N. Uma, 2010: MST radar investigation on inertia-gravity waves associated with tropical depression in the upper troposphere and lower stratosphere over Gadanki (13.5^\circN,79.2^\circE). Journal of Atmospheric and Solar-Terrestrial Physics, 72, 1184-1194, doi: 10.1016/j.jastp. 2010.07.016.10.1016/j.jastp.2010.07.016

9e41057d6cedaca93e48e01778931383

http%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Farticle%2Fpii%2FS1364682610002129

http://www.sciencedirect.com/science/article/pii/S1364682610002129Continuous measurements of 3-dimensional winds, spectral parameters, and tropopause height for 藴114 h during the passage of a tropical depression using mesosphere-stratosphere-troposphere (MST) radar at Gadanki (13.5°N, 79.2°E) are discussed. The spectral analysis of zonal and meridional winds shows the presence of inertia-gravity wave (IGW) with the dominant periodicity of 56 h and intrinsic period of 27 h in the upper troposphere and lower stratosphere (UTLS). The strengthening of easterly jet and associated wind shears during the passage of the depression is one of the causative mechanisms for exciting the IGW. A well-established radar method is used to identify the tropopause and to study its response to the propagating atmospheric disturbances. The significance of the present study lies in showing the response of tropopause height to the IGW during tropical depression for the first time, which will have implications in stratosphere-troposphere exchange processes. Continuous measurements of 3-dimensional winds, spectral parameters, and tropopause height for 藴114 h during the passage of a tropical depression using mesosphere-stratosphere-troposphere (MST) radar at Gadanki (13.5°N, 79.2°E) are discussed. The spectral analysis of zonal and meridional winds shows the presence of inertia-gravity wave (IGW) with the dominant periodicity of 56 h and intrinsic period of 27 h in the upper troposphere and lower stratosphere (UTLS). The strengthening of easterly jet and associated wind shears during the passage of the depression is one of the causative mechanisms for exciting the IGW. A well-established radar method is used to identify the tropopause and to study its response to the propagating atmospheric disturbances. The significance of the present study lies in showing the response of tropopause height to the IGW during tropical depression for the first time, which will have implications in stratosphere-troposphere exchange processes.

Das S. S., K. N. Uma, and S. K. Das, 2012: MST radar observations of short-period gravity wave during overhead tropical cyclone. Radio Sci., 47,RS2019, doi: 10.1029/2011RS 004840.

Dewan E. M., 1979: Stratospheric wave spectra resembling turbulence. Science,204, 832-835, doi: 10.1126/science.204. 4395.832.10.1126/science.204.4395.832

17730524

5672ddb68d8605afef833153ab1a4531

http%3A%2F%2Fonlinelibrary.wiley.com%2Fresolve%2Freference%2FADS%3Fid%3D1979Sci...204..832D

http://med.wanfangdata.com.cn/Paper/Detail/PeriodicalPaper_PM17730524Pollution effects on ozone raise the question of the significance of turbulence in vertical transport in the stratosphere. The aircraft in situ measurements of velocity fluctuations previously employed to estimate turbulence transport were, it is hypothesized, due to atmospheric waves, despite their classical turbulence spectrum. This new hypothesis implies that previous turbulence estimates are invalid. Experimental tests are suggested.

Dhaka S. K., P. K. Devrajan, Y. Shibagaki, R. K. Choudhary, and S. Fukao, 2001: Indian MST radar observations of gravity wave activities associated with tropical convection. Journal of Atmospheric and Solar-Terrestrial Physics, 63, 1631- 1642.10.1016/S1364-6826(01)00040-2

cef486066f58e58bd56a8577ca8a3b12

http%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Farticle%2Fpii%2FS1364682601000402

http://www.sciencedirect.com/science/article/pii/S1364682601000402MST radar observations at Gadanki ja:math of high frequency (few tens of minutes) gravity waves generated most likely by convection are presented. The experiments were conducted during the months of May–June (19 May 1995, 05 June 1995 and 06 June 1996) of summer season, which is likely to be highly convective after the onset of south–west monsoon over southern part of India. The excitation and vertical propagation of gravity waves are found to display specific characteristics pointing convection as a main source. The intriguing characteristics of rising reflectivity pattern, coupled with rise in vertical wind component and turbulence from lower troposphere to upper troposphere within hour of time (on 19 May 1995 and 06 June 1996) are noticed. On the other day of experiment, horizontal large spread in reflectivity pattern confined mostly below ja:math of altitude has been observed. During this period wind disturbances are found to posses comparatively large magnitude of momentum flux at mid-tropospheric levels. Usually enhanced reflectivity regions are found to be accompanied by strong updraft and downdraft in vertical wind component ( w ). An interesting feature in the case of 05 June 1995 is the appearance of vertical wind disturbances well up to lower stratosphere. The effect of these enhanced vertical wind is in conformity with the observed increase in the momentum flux values even up to lower stratospheric altitudes. Typical wave amplitude in vertical wind disturbances during convection vary from 1– ja:math with some sudden enhancement in amplitude of the order of 8– ja:math for some short interval of time. An effort has been made to discuss these results in the light of existing theoretical concepts viz. mechanical oscillator effect, obstacle effect and direct thermal forcing for generating the convection waves (gravity waves generated due to convection).

Dhaka S. K., M. Takahashi, Y. Kawatani, S. Malik, Y. Shibagaki, and S. Fukao, 2003: Observations of deep convective updrafts in tropical convection and their role in the generation of gravity waves. J. Meteor. Soc.Japan, 81, 1185- 1199.10.2151/jmsj.81.1185

3ed22cbdaa841a716d589cc742a62bab

http%3A%2F%2Fci.nii.ac.jp%2Fnaid%2F10013698168

http://ci.nii.ac.jp/naid/10013698168ABSTRACT A few sequential strong updrafts of magnitude about 8–10 m/s in the upper troposphere were ob-served by the MST radar at Gadanki (13.5 N, 79.2 E), India on 21–22 and 22–23 June 2000. On both days, convective storms with rainfall appeared over the radar site. The updrafts region shifted upward by a distance of about 3–4 km within a time-range of 8–10 minutes, and terminated around 15–16 km (the level of neutral buoyancy). The signature of the gravity wave was seen in both the upper tropo-sphere and lower stratosphere. The main mechanism involved in the generation of the gravity waves most likely came from a vertically oriented oscillator, which triggered by convective updrafts near the neutral buoyancy level analogous to the mechanical oscillator. The resultant gravity waves had a verti-cal wavelength of about 2–5 km, and dominant wave periods of 10–20 minutes (above tropopause) and @10 minute (below tropopause). However, variations whose period is below 10 minutes in the tropo-sphere are thought to be not due to the gravity waves, but due to oscillatory behavior of the updrafts. The horizontal wavelengths, and intrinsic group velocity corresponding to these gravity waves, in the lower stratosphere, are estimated in the range of 10 to 20 km, and 10–12 m/s, respectively. The direction of average group velocity is estimated at about 15–20 degrees from the horizontal.

Dutta G., B. Bapiraju, T. S. P. L. N. Prasad, P. Balasubrahmanyam, and H. A. Basha, 2005a: Vertical wave number spectra of wind fluctuations in the troposphere and lower stratosphere over Gadanki,a tropical station. Journal of Atmospheric and Solar-Terrestrial Physics, 67, 251-258, doi: 10.1016/J.JASTP.2004.08.003.10.1016/j.jastp.2004.08.003

8bcc9a9242393139f449cd56c8cd8f71

http%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Farticle%2Fpii%2FS136468260400224X

http://www.sciencedirect.com/science/article/pii/S136468260400224XSpectral analyses of horizontal and vertical winds measured by Gadanki (13.5°N, 79.2°E) MST radar in the troposphere and lower stratosphere have been presented. Average slopes of the wave number spectra obtained in the power-law region are 612.5 for horizontal winds and 612.2 for vertical winds. Spectral indices are found to vary in different altitude zones with steepest slopes in the tropopause region for both horizontal and vertical winds. A seasonal variation of the slope has also been observed with higher value in summer. The ratio of the spectral magnitudes between the stratosphere and troposphere is found to be quite variable with an average value of 4.2 and 5.5 for horizontal and vertical winds, respectively. The power-law region seems to be dominated by gravity wave fluctuations and high correlations are observed between horizontal and vertical winds and between stratospheric and tropospheric energy densities. It is suggested that the saturated gravity wave model may be modified to match the observed spectral features. Spectral growth is found to be inhibited on some days which cannot be explained by gravity wave theory. It is felt that mesoscale spectra can be influenced by mechanism like 2D-turbulence.

Dutta G., B. Bapiraju, P. V. Rao, A. I. Sheeba, M. C. Ajay Kumar, P. Balasubrahmanyam, and H. A. Basha, 2005b: Comparison of gravity wave momentum fluxes estimated by different methods using mesosphere-stratosphere-troposphere radar. Radio Sci.,40, RS4009, doi. 10.1029/2004RS003031.10.1029/2004RS003031

5791b34213e411748c8dfe1baa3e69f4

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2004RS003031%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/2004RS003031/fullMesosphere-stratosphere-troposphere radar measurements have been used to estimate momentum flux of gravity waves in a 2-6 hour period in the lower atmosphere over Gadanki (13.5°N, 79.2°E), a tropical station. Different methods have been adopted to compute momentum flux profiles, and a comparative study shows that momentum flux estimates produced by a hybrid method (Worthington and Thomas, 1996) which measures the vertical wind with a vertical beam and the horizontal wind with a pair of radial beams and those obtained by direct computation of spatial covariances (? and ?) show satisfactory agreement. The symmetric beam radar method of Vincent and Reid (1983) has the unique advantage since it does not require vertical beam measurement, and it is found to produce momentum flux estimates compatible with other methods except in high wind shear zones. It is observed that the result of momentum flux obtained by the symmetric beam method shows excellent matching with other methods when the average of vertical winds derived from E-W and N-S beams is used in the formula for both zonal and meridional fluxes.

Dutta G., M. C. Ajay Kumar, P. Vinay Kumar, M. Venkat Ratnam, M. Chand rashekar, Y. Shibagaki, M. Salauddin, and H. A. Basha, 2009a: Characteristics of high-frequency gravity waves generated by tropical deep convection: Case studies. J. Geophys. Res., 114,D18109, doi: 10.1029/2008JD011332.10.1029/2008JD011332

b56c06b2141393d8e1cb3496f686d8cb

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2008JD011332%2Fpdf

http://onlinelibrary.wiley.com/doi/10.1029/2008JD011332/pdfHigh-frequency gravity waves generated by tropical deep convection play a major role in shaping the general circulation of the middle atmosphere. Special experiments were conducted to capture two convective events on 16 May and 5 June 2006 using VHF radar located at Gadanki (13.5°N, 79.2°E), a tropical Indian station. Control day observations were also made for necessary comparisons. Background wind and temperature information was obtained by GPS radiosonde flights launched from the same site. This work has utilized these valuable data sets to delineate characteristics of convectively generated gravity waves. A superposition of gravity waves is observed with different scales after the deep convective events. Vertical wave number spectra of radial velocities show steeper slopes and higher power spectral densities during convection which slowly reduce to their normal values. The present case studies suggest the mechanical oscillator mechanism to be a major source of convective gravity wave generation in the tropics. Estimates of vertical wind variances and momentum fluxes of short-period (<2 h) wind fluctuations show large enhancements on convective days in comparison to control days. The momentum flux frequency spectra revealed a higher contribution of 30-65 min wave periods to the mean profile in the lower stratosphere. The wavelet transform momentum flux spectra displayed the temporal variability and discretization of the gravity wave momentum fluxes in frequency and time.

Dutta G., M. C. Ajay Kumar, P. Vinay Kumar, P. V. Rao, B. Bapiraju, and H. A. Basha, 2009b: High resolution observations of turbulence in the troposphere and lower stratosphere over Gadanki. Annales Geophysicae, 27, 2407- 2415.10.5194/angeo-27-2407-2009

8e42b92a446a01efae3827ccbe83c5bb

http%3A%2F%2Fwww.oalib.com%2Fpaper%2F1368269

http://www.oalib.com/paper/1368269High resolution (150 m) wind measurements from 13-17 July 2004 by Mesosphere-Stratosphere-Troposphere (MST) radar and 15-16 July 2004 by Lower Atmospheric Wind Profiler (LAWP) have been used to study the time variation of turbulence intensity. Layers of higher turbulence are observed in the lower stratosphere on 15-16 July which give rise to mixing in the region. Enhancement in short-period gravity wave activity and turbulent layers are observed after 22:00 LT which could be due to a dry convection event that occurred at that time. The breakdown of the convectively generated high frequency waves seems to have given rise to the turbulence layers. Wind shear is found to be high above the easterly jet, but very poor correlation is observed between square of wind shear and turbulence parameters in the region. The heights of the turbulent layers in the lower stratosphere do not correlate with levels of minimum Richardson number. A monochromatic inertia gravity wave could be identified during 13-17 July 2004. A non-linear interaction between the waves of different scales as proposed by Hines (1992) might also be responsible for the breakdown and generation of turbulence layers.

Fovell R., D. Durran, and J. R. Holton, 1992: Numerical simulations of convectively generated stratospheric gravity waves. J. Atmos. Sci.,49, 1427-1442, doi: 10.1175/1520-0469(1992) 049<1427:NSOCGS>2.0.CO;2.10.1175/1520-0469(1992)049<1427:NSOCGS>2.0.CO;2

0651850a32e85cbf1df9dc34a2336b44

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1992JAtS...49.1427F

http://adsabs.harvard.edu/abs/1992JAtS...49.1427FThe cloud model results are compared with results from a dry model in which waves are excited by a specified compact momentum source designed to mimic the mechanical forcing caused by the regular development and rearward propagation of updraft cells. Results from this analog strongly support the notion that squall-line-generated gravity waves arise from mechanical forcing rather than thermal effects.

Fritts D. C., T. Tsuda, T. E. VanZand t, S. A. Smith, T. Sato, S. Fukao, and S. Kato, 1990: Studies of velocity fluctuations in the lower atmosphere using the MU radar. Part II: Momentum fluxes and energy densities. J. Atmos. Sci., 47, 51- 66.10.1175/1520-0469(1990)047<0051:SOVFIT>2.0.CO;2

d270a649-a578-4fe0-b5f5-c56ddc2504d8

a0f2690a3bb12b8765197c3148ad0b07

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1990JAtS...47...51F

refpaperuri:(cddb072c28d9606f445cc8c49163790b)

http://adsabs.harvard.edu/abs/1990JAtS...47...51FNot Available

Fukao S., T. Sato, T. Tsuda, S. Kato, M. Inaba, and I. Kimura, 1988: VHF Doppler radar determination of the momentum flux in the upper troposphere and lower stratosphere: Comparison between the three- and four-beam methods. J. Atmos. Oceanic Technol., 5, 57- 69.10.1175/1520-0426(1988)0052.0.CO;2

921f6a46-6a54-4a0e-88dd-4104a9bbce71

078d5467eac9f6c1119d1fde9a7d2481

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1988JAtOT...5...57F

refpaperuri:(0b209088fd43714379f147d75c1eb3e3)

http://adsabs.harvard.edu/abs/1988JAtOT...5...57FThis paper discusses methods for measuring the vertical flux of horizontal momentum in the upper troposphere and lower stratosphere with VHF Doppler radars. Two versions of the mesosphere-stratosphere-troposphere radar technique are compared: one using three beams, of which one is vertical and two oblique; the other using four beams, which were two pairs of oblique beams symmetrically offset from the vertical. Using an MU (middle and upper atmosphere) radar which made it possible to make the three- and four-beam measurements simultaneously, it was found that the three-beam flux agreed with the four-beam flux only for long-period (longer than 6 h) wind fluctuations. For shorter periods, a systematic error in the three-beam method, caused by wind fluctuations, was observed.

Gage K. S., 1979: Evidence for a k^-5/3 law inertial range in mesoscale two-dimensional turbulence. J. Atmos. Sci., 36, 1950- 1954.

Ghosh A. K., V. Siva Kumar, K. Kishore Kumar, and A. R. Jain, 2001: VHF radar observation of Atmospheric winds, associated shears and C_n² at a tropical location: Interdependence and seasonal pattern. Annales Geophysicae, 19, 965- 973.10.5194/angeo-19-965-2001

221ab04f-d2af-415c-ae13-8d6faa232320

3d2f19b00509026c9bc99054a176ed5e

http%3A%2F%2Fwww.oalib.com%2Fpaper%2F2549389

refpaperuri:(b9316557f7465b874dc194b70da4aeb0)

http://www.oalib.com/paper/2549389The turbulence refractivity structure constant (C) is an important parameter of the atmosphere. VHF radars have been used extensively for the measurements of C. Presently, most of such observations are from mid and high latitudes and only very limited observations are available for equatorial and tropical latitudes. Indian MST radar is an excellent tool for making high-resolution measurements of atmospheric winds, associated shears and turbulence refractivity structure constant (C). This radar is located at Gadanki (13.45° N, 79.18° E), a tropical station in India. The objective of this paper is to bring out the height structure of Cfor different seasons using the long series of data (September 1995 August 1999) from Indian MST radar. An attempt is also made to understand such changes in the height structure of Cin relation to background atmospheric parameters such as horizontal winds and associated shears. The height structure of C, during the summer monsoon and post-monsoon season, shows specific height features that are found to be related to Tropical Easterly Jet (TEJ) winds. It is important to examine the nature of the radar back-scatterers and also to understand the causative mechanism of such scatterers. Aspect sensitivity of the received radar echo is examined for this purpose. It is observed that radar back-scatterers at the upper tropospheric and lower stratospheric heights are more anisotropic, with horizontal correlation length of 10 20 m, as compared to those observed at lower and middle tropospheric heights.

Hines C. O., 1995: Comments on "Observations of low-frequency inertia-gravity waves in the lower stratosphere over Arecibo". J. Atmos. Sci., 52, 607- 610.10.1175/1520-0469(1995)052<0607:COOLFI>2.0.CO;2

d5e1b67e-6eca-4b0e-b1f3-a9bcef8468ab

77a271429a85172dfd94874db2a478d2

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1995JAtS...52..607H

refpaperuri:(e14e3489644006a47d9e6fdc42340773)

http://adsabs.harvard.edu/abs/1995JAtS...52..607HComments on the article `Observations of low-frequency inertia-gravity waves in the lower stratosphere over Arecibo,' by C. R. Cornish and M. F. Larsen from the Journal of Atmospheric Sciences. Horizontal wavelengths; Theory of freely propagating inertia-gravity waves.

Hocking W. K., 1985: Measurement of turbulent energy dissipation rates in the middle atmosphere by radar techniques: A review. Radio Sci., 20, 1403- 1422.10.1029/RS020i006p01403

7749a8eb93a183d1500f1e92ef104e5d

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2FRS020i006p01403%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/RS020i006p01403/fullRadars operating in the frequency band between 2 MHz and several hundred megahertz are capable of supplying a large data base of measurements of turbulent energy dissipation rates in the middle atmosphere. So far this has not been achieved; only occasionally have such radars been used to produce estimates of turbulence intensities. In order to encourage a greater emphasis on this aspect of radar studies of the middle atmosphere, this review summarizes the various techniques which can be used to measure turbulent energy dissipation rates. It is shown how absolute measurements of backscatter cross section can be used to measure turbulence intensities. A new theory is presented which shows that the power backscattered from the mesosphere depends on the turbulent energy dissipation rate, the electron density gradient, the neutral density scale height, the total electron density and the temperature gradient. The effects of turbulence on the width of signal spectra received by these radars are discussed, and it is shown how turbulence intensities may be extracted from spectral width measurements. The importance of removing nonturbulent processes which also broaden the width of the power spectra, such as wind shear broadening and beam width broadening, are stressed.

Hooper D. A., L. Thomas, 1998: Complementary criteria for identifying regions of intense Atmospheric turbulence using lower VHF radar. Journal of Atmospheric and Solar-Terrestrial Physics, 60, 49- 61.10.1016/S1364-6826(97)00054-0

040fe112206b5295b20be8b86b414e40

http%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Farticle%2Fpii%2FS1364682697000540

http://www.sciencedirect.com/science/article/pii/S1364682697000540Use is made of data from three campaigns of combined multi-beam lower VHF radar and radiosonde observations of the troposphere and lower stratosphere at Aberystwyth (52.4°N, 4.1°W). These provide altitude profiles of the usual radar signal parameters in addition to those of the Brunt-V01is01l01 frequency, ω, and the gradient Richardson number, Ri. It is shown that the signal strength observed by a radar beam directed 12° off-vertical, which is expected to represent backscatter alone, is not necessarily enhanced within regions identified by Ri as containing intense turbulence. Furthermore, perturbations of the signal strength altitude profiles are associated with those of the ωprofile. The possibility that Fresnel scatter contributes to radar returns at such a large zenith angle cannot be discounted. It is shown that regions of intense turbulence can, however, be identified by a combination of an absence of aspect sensitivity of radar returns, an enhancement of vertical beam spectral width, which has been corrected for the effect of beam broadening, and values of Ri close to or less than 1/(4). This method has highlighted the presence of layers of intense turbulence which follow descending phase fronts of long-period gravity waves in the lower stratosphere.

Ito H., 1963: Aspects of typhoon development. Proc. Inter-Regional Seminar on Tropical Cyclones, Tokyo, Japan Meteor Agency, 103- 119.

Kim S. Y., H. Y. Chun, and J. J. Baik, 2005: A numerical study of gravity waves induced by convection associated with Typhoon Rusa. Geophys. Res. Lett., 32, L24816, doi. 10.1029/2005GL024662.10.1029/2005GL024662

4ef301814cd3ff448788424c35207692

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2005GL024662%2Fabstract

http://onlinelibrary.wiley.com/doi/10.1029/2005GL024662/abstract[1] Typhoon Rusa (2002) is simulated using a three-dimensional mesoscale model (MM5), and the characteristics of gravity waves generated by convection associated with the typhoon are investigated. The gravity waves in the stratosphere propagate in two directions, northwestward and southeastward according to the convective bands propagating in the same directions, although the typhoon itself moves north-northeastward. Spectral analyses show that the inertio-gravity waves (IGWs) in the stratosphere generated by Rusa have a dominant horizontal wavelength of 300–600 km, a vertical wavelength of 3–11 km, and a period of 6–11 hrs. A large fraction of the IGWs is filtered out in the upper troposphere and stratosphere mainly due to the critical-level filtering process. The decreased magnitude of the momentum flux with height in a non-filtered region is likely due to the damping process, with a minor contribution by the wave breaking process that can occur exclusively near the critical-level phase speeds.

Kim S. Y., H. Y. Chun, and J. J. Baik, 2007: Sensitivity of Typhoon-induced gravity waves to cumulus parameterizations. Geophys. Res. Lett., 34,L15814, doi: 10.1029/2007GL 030592.10.1029/2007GL030592

541e2e761d4569f8f23a2bfbc5102ae5

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2007GL030592%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/2007GL030592/fullSensitivity of typhoon-induced gravity waves to cumulus parameterizations is examined using a mesoscale model (MM5). For this, Typhoon Rusa (2002) is simulated with four cumulus parameterizations (Kain-Fritsch, Grell, Anthes-Kuo, and Betts-Miller schemes) and the characteristics of typhoon-induced gravity waves are compared. The experiments show differences in rainband structure and vertical motion, resulting in different forcing spectra for zonal wavelength and period. As a result, induced stratospheric gravity waves are different in amplitude and spectral shape. However, the difference is not as large as that in the forcing spectrum, since a large portion of the waves generated by major forcing components is filtered out by the background wind, which is nearly the same in all the experiments. Instead, variation in zonal wavelength and period of forcing modifies the characteristics of stratospheric gravity waves by changing damping time scale in the nonfiltered region.

Kudeki E., S. J. Franke, 1998: Statistics of momentum flux estimation. Journal of Atmospheric and Solar-Terrestrial Physics, 60, 1549- 1553.10.1016/S1364-6826(98)00104-7

d5f7b7ebd80db6eb4fae2afd35a94060

http%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Farticle%2Fpii%2FS1364682698001047

http://www.sciencedirect.com/science/article/pii/S1364682698001047The effect of geophysical noise on the precision of momentum flux measurements is examined. The dominant contribution to the uncertainty of momentum flux estimates scales with the geometric mean of the energy in horizontal and vertical wind fluctuations. To obtain statistically significant measurements of the momentum flux, long integration times are necessary since the flux is typically a small fraction of the geometric mean energy. For example, when the fraction is 1%, at least 16 days of stratospheric measurements will be needed for reliable flux estimation.

Larsen M. F., 1995: Reply with comments on "Modulated mountain waves". J. Atmos. Sci., 52, 611- 612.10.1175/1520-0469(1995)0522.0.CO;2

0cd72ccd-51a5-4d79-9def-f7a123911223

ee98d4b2741bf959afd304c30fefc1e0

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1995JAtS...52..611L

refpaperuri:(53489df58889c4903022dffb3ad7a0d0)

http://adsabs.harvard.edu/abs/1995JAtS...52..611LAbstract No abstract available

Lilly D. K., 1983: Stratified turbulence and the mesoscale variability of the atmosphere. J. Atmos. Sci., 40, 749- 761.b61272dd0681d72247ddc54b98dbd457

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1983jats...40..749l

/s?wd=paperuri%3A%288f7b2cf74a74a367ee9decf0994878f9%29&filter=sc_long_sign&tn=SE_xueshusource_2kduw22v&sc_vurl=http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1983jats...40..749l&ie=utf-8&sc_us=930892207254960111

McLandress C., M. J. Alexand er, D. L. Wu, 2000: Microwave Limb Sounder observations of gravity waves in the stratosphere: A climatology and interpretation. J. Geophys. Res., 105, 11 947- 11 967.10.1029/2000JD900097

4d7c9375915db5646db4118963f3bbe2

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2000JD900097%2Fabstract

http://onlinelibrary.wiley.com/doi/10.1029/2000JD900097/abstractHigh-horizontal-resolution temperature data from the Microwave Limb Sounder (MLS) are analyzed to obtain information about high intrinsic frequency gravity waves in the stratosphere. Global climatologies of temperature variance at solstice are computed using six years of data. A linear gravity wave model is used to interpret the satellite measurements and to infer information about tropospheric wave sources. Globally uniform sources having several different spectral shapes are examined and the computed variances are filtered in three-dimensional space in a manner that simulates the MLS weighting functions. The model is able to reproduce the observed zonal mean structure, thus indicating that the observations reflect changes in background wind speeds and provide little information about the latitudinal variation of wave sources. Longitudinal variations in the summer hemisphere do reflect source variations since the modeled variances exhibit much less variation in this direction as a consequence of the zonal symmetry of the background winds. A close correspondence between the MLS variances and satellite observations of outgoing-longwave radiation suggests that deep convection is the probable source for these waves. The large variances observed over the tip of South America in winter are most certainly linked to orographic forcing but inferences about wave sources in Northern Hemisphere winter are difficult to make as a result of the high degree of longitudinal and temporal variability in the stratospheric winds. Comparisons of model results using different source spectra suggest that the tropospheric sources in the subtropics in summer have a broader phase speed spectrum than do sources at middle latitudes in winter.

Nastrom G. D., F. D. Eaton, 2001: Persistent layers of enhanced C_n² in the lower stratosphere from VHF radar observations. Radio Sci., 36, 137- 149.10.1029/2000RS002318

54c56453-8dea-4ee4-adc2-b6fd6bd6d02e

94d661e1e35ae5334ca99acca9eebebd

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2000RS002318%2Fabstract

refpaperuri:(3b93e3d961a1e2306b853e565799ab13)

http://onlinelibrary.wiley.com/doi/10.1029/2000RS002318/abstractSeasonal climatologies of persistent layers of enhanced refractive index structure parameter C 2 N were developed for the lower stratosphere from VHF radar observations at White Sands Missile Range, New Mexico, for the period January 1991 to September 1996. Knowledge of the nature of enhanced refractivity layers is of high interest to the atmospheric sciences, propagation, and remote sensing communities. The layers reported have C 2 N enhanced at least 7 dB above the background continuously for at least 11 hours and migrate vertically no more than one radar range gate (150 m) over 1 hour. The cumulative frequency of the lengths (11-37 hours) of the 259 persistent layers identified shows that 25% of the layers last over 17 hours. Comparisons of profiles of wind speeds, variances of the wind components, vertical shear of the horizontal wind, Doppler spectral width, temperature, Brunt-Vaisala frequency, and Richardon's number for times with and without persistent layers at 17 km show that wind speed at 5.6 km in addition to spectral width, wind shear, and vertical velocity variances at 17 km are stronger during enhanced layer episodes than during nonlayer periods. Possible sources for the persistent layers are suggested, and the shortcomings of each hypothesis are discussed. Several case studies of radiosonde ascents during persistent layers give no obvious indication of the source of these layers.

Nastrom G. D., T. E. VanZand t, and J. M. Warnock, 1997a: Vertical wavenumber spectra of wind and temperature from high-resolution balloon soundings over Illinois. J. Geophys. Res., 102, 6685- 6701.10.1029/96JD03784

e8eb4142fe85f85027b39afdaa58618d

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F96JD03784%2Fcitedby

http://onlinelibrary.wiley.com/doi/10.1029/96JD03784/citedbyWe spectrally analyzed high-resolution balloon measurements of vertical profiles of temperature and horizontal wind in the troposphere and lower stratosphere over very flat terrain in Illinois. This paper is principally concerned with spectra in the power law range at vertical wavenumbers m ≥10cycle/m. The logarithmic spectral slopes and amplitudes are found to have only insignificant dependencies on meteorological parameters, including time of day, season, wind speed and direction, vertical shear, etc., except that between the troposphere and stratosphere the spectral amplitude scales as (N)with q 000.3, where N is the buoyancy frequency. The mean slopes are ≈-3 in the stratosphere and ≈ -2.6 in the troposphere. On the average the individual spectra with larger amplitudes have less negative spectral slopes. The wide variation of spectral slopes (σ≈0.5) and amplitudes and the weak dependence on Nare quite inconsistent with the predictions of theories of saturated spectra. Further, the wind spectra in the troposphere and stratosphere are correlated, which suggests some unsaturated propagation between the regions. The ratio of kinetic to potential energy spectra is constant versus m, consistent with the linear gravity wave polarization relations. The magnitude of the model ratio can be brought into agreement with the observed ratio by assuming a model intrinsic frequency spectrum varying as ωwith p 005/3 to 2 plus an enhancement of energy near the inertial frequency.

Nastrom G. D., T. E. VanZand t, and F. D. Eaton, 1997b: Long-lived layers of enhanced reflectivity in the lower stratosphere. Paper presented at 8th Workshop on Technical and Scientific Aspects of MST Radars, Bangalore, India, Scientific Communication on Solar Terr Phys Bangalore, 15- 20.

Nath D., W. Chen, 2013: Investigating the dominant source for the generation of gravity waves during Indian Summer Monsoon using ground-based measurements. Adv. Atmos. Sci.,30, 153-166, doi: 10.1007/s00376-012-1273-y.10.1007/s00376-012-1273-y

3e244946af4f554c6f60ebdcabf3e687

http%3A%2F%2Fd.wanfangdata.com.cn%2FPeriodical_dqkxjz-e201301015.aspx

http://d.wanfangdata.com.cn/Periodical_dqkxjz-e201301015.aspxOver the tropics, convection, wind shear (i.e., vertical and horizontal shear of wind and/or geostrophic adjustment comprising spontaneous imbalance in jet streams) and topography are the major sources for the generation of gravity waves. During the summer monsoon season (June-August) over the Indian subcontinent, convection and wind shear coexist. To determine the dominant source of gravity waves during monsoon season, an experiment was conducted using mesosphere-stratosphere-troposphere (MST) radar situated at Gadanki (13.5°N, 79.2°E), a tropical observatory in the southern part of the Indian subcontinent. MST radar was operated continuously for 72 h to capture high-frequency gravity waves. During this time, a radiosonde was released every 6 h in addition to the regular launch (once daily to study low-frequency gravity waves) throughout the season. These two data sets were utilized effectively to characterize the jet stream and the associated gravity waves. Data available from collocated instruments along with satellite-based brightness temperature (TBB) data were utilized to characterize the convection in and around Gadanki. Despite the presence of two major sources of gravity wave generation (i.e., convection and wind shear) during the monsoon season, wind shear (both vertical shear and geostrophic adjustment) contributed the most to the generation of gravity waves on various scales.

Nayar S. R. P., S. Sreeletha, 2003: Momentum flux associated with gravity waves in the low-latitude troposphere. Annales Geophysicae, 21, 1183- 1195.10.5194/angeo-21-1183-2003

e35e9aa9ed621b509c27744e9166cb85

http%3A%2F%2Fwww.oalib.com%2Fpaper%2F2548131

http://www.oalib.com/paper/2548131The vertical fluxes of horizontal momentum at tropospheric heights are calculated for four days, 25-28 August 1999. The mean zonal wind during these days show the presence of strong westward wind at the upper troposphere. Both the symmetric beam radar method and the power spectral method of evaluation of vertical flux of zonal and meridional momentum shows nearly the same result for quiet conditions. The temporal evolution of the momentum flux is estimated for a day with strong zonal shear and convection. These results indicate that on 28 August 1999, the strong downward vertical wind in the lower altitude range is associated with upward vertical flux of zonal momentum, and strong upward vertical wind is associated with downward vertical flux. Similarly, the strong shear in zonal wind is associated with the increase in negative values in vertical flux in the upper troposphere. Analysis of the role of wave periods in the transport of momentum flux indicates that the vertical momentum flux magnitude is not evenly distributed in all wave periods, but instead it peaks at certain wave periods in the range 10 to 100 min. Key words. Meteorology and atmospheric dynamics (convective process; tropical meteorology; precipitation)

Niranjan Kumar K., T. K. Ramkumar, 2008: Characteristics of inertia-gravity waves over Gadanki during the passage of a deep depression over the Bay of Bengal. Geophys. Res. Lett., 35,L13804, doi: 10.1029/2008GL033937.10.1029/2008GL033937

fd5ef73ef095fd575d47c0161ebd4c1a

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2008GL033937%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/2008GL033937/fullUsing MST Radar located at the Indian tropical station of Gadanki (13.5°N, 79.2°E near the eastern coast of India), studies have been made on the characteristics of inertia-gravity waves generated in the lower troposphere during deep depression developed over the Bay of Bengal on 20-24 June 2007. Filtering and the hodograph analyses of horizontal winds indicate that the low-pressure system has generated inertia gravity waves, propagating outward from the core of the depression. Strong enhancement of radar reflectivity (SNR) in the heights of ~4-7 km for a few days around 22 June 2007 and the upward propagation of gravity wave energy above this height range indicate that the source of the waves is located at ~4-7 km. This is in agreement with earlier theoretical expectations. The vertical and horizontal wavelengths of gravity waves are found to be ~2.2 km and ~240 km respectively in the troposphere.

Niranjan Kumar, K., T. K. Ramkumar, M. Krishnaiah, 2011: MST radar observation of inertia-gravity waves generated from tropical cyclones. Journal of Atmospheric and Solar-Terrestrial Physics, 73, 1890- 1906.10.1016/j.jastp.2011.04.026

c72680ce4e0c4da3b9242feeaa610d59

http%3A%2F%2Fwww.sciencedirect.com%2Fscience%2Farticle%2Fpii%2FS1364682611001416

http://www.sciencedirect.com/science/article/pii/S1364682611001416Using a Mesosphere Stratosphere Troposphere (MST) radar, operating at 5302MHz at Gadanki (13.5°N, 79.2°E), India, the present study reports on the temporal and spatial characteristics of inertia-gravity waves (IGWs) generated from four tropical cyclones that formed over the Bay of Bengal. IGWs are observed with intrinsic frequencies, vertical and horizontal wavelengths in the ranges of 1.2 f –3.0 f , 2.5–5, and 300–160002km, respectively, where f is the Coriolis frequency at the Gadanki site. It is found that both the convective and geostrophic adjustment processes in the troposphere play a major role in the generation of IGWs. Also it is found that the horizontal propagation direction of IGWs is aligned along the motion of convective rain bands.

Pfister, L., Coauthors, 1993: Gravity waves generated by a tropical cyclone during the STEP tropical field program: A case study. J. Geophys. Res., 98( D5), 8611- 8638.10.1029/92JD01679

a664d2ec52a7ccbc03a4358f3dc02cd0

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F92JD01679%2Fcitedby

http://onlinelibrary.wiley.com/doi/10.1029/92JD01679/citedbyOverflights of a tropical cyclone during the Australian winter monsoon field experiment of the Stratosphere-Troposphere Exchange Project (STEP) show the presence of two mesoscale phenomena: a vertically propagating gravity wave with a horizontal wavelength of about 110 km and a feature with a horizontal scale comparable to that of the cyclone's entire cloud shield (wavelength of 250 km or greater). The larger feature is fairly steady, though its physical interpretation is ambiguous. The 110-km gravity wave is transient, having maximum amplitude early in the flight and decreasing in amplitude thereafter. Its scale is comparable to that of 100-to 150-km-diameter cells of low satellite brightness temperatures within the overall cyclone cloud shield; these cells have lifetimes of 4.5 to 6 hours. Aircraft flights through the anvil show that these cells correspond to regions of enhanced convection, higher cloud altitude, and upwardly displaced potential temperature surfaces. A three-dimensional transient linear gravity wave simulation shows that the temporal and spatial distribution of meteorological variables associated with the 110-km gravity wave can be simulated by a slowly moving transient forcing at the anvil top having an amplitude of 400-600 m, a lifetime of 4.5-6 hours and a size comparable to the cells of low brightness temperature. The forcing amplitudes indicate that the zonal drag due to breaking mesoscale transient convective gravity waves is definitely important to the westerly phase of the stratopause semiannual oscillation and possibly important to the easterly phase of the quasi-biennial oscillation. There is strong evidence that some of the mesoscale gravity waves break below 20 km as well. The effect of this wave breaking on the diabatic circulation below 20 km may be comparable to that of above-cloud diabatic cooling.

Rao D. N., P. Kishore, T. N. Rao, S. V. B. Rao, K. K. Reddy, M. Yarraiah, and M. Hareesh, 1997: Studies on refractivity structure constant, eddy dissipation rate, and momentum flux at a tropical latitude. Radio Sci., 32( 5), 1375- 1389.10.1029/97RS00251

a08a0fdc97a48215f355171c2617513c

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F97RS00251%2Fpdf

http://onlinelibrary.wiley.com/doi/10.1029/97RS00251/pdfVHF and UHF Doppler radars provide a unique database to estimate the refractivity structure constant C, eddy dissipation rate 鈭, and vertical flux of horizontal momentum. Using the data collected from the Indian MST radar, these parameters are studied at a tropical latitude. The refractivity turbulence structure constant is estimated from the backscattered power of the received echoes. C(radar) and C(model), derived from radiosonde observations, are compared, and a fairly good agreement is seen. Diurnal and seasonal variations of Care also presented. The eddy dissipation rate is estimated from the radar echoes employing the power and spectral width methods. A fairly good agreement is seen between the two methods. Values of 蓻 are found to vary from 10to 10msin a height range of 4-19 km. Cand 蓻 are observed to be minimum during a moderate jet stream wind of 50-60 m s. Vertical flux of horizonal momentum is computed using the symmetrical two-beam method. Significant fluxes of westward and northward momentum are observed, and the values lie in the range of -1 to +1 ms. The implied accelarations are also estimated. The results presented are largely consistent with the results available in the literature.

Rao J. Y., 1998: A study of Atmospheric stable layers in the tropical atmosphere using Indian MST radar. Ph.D. dissertation, Sri Venkateswara University, 172 pp.2072ae55cd857d63d4565bdde49a5340

http%3A%2F%2Fir.inflibnet.ac.in%3A8080%2Fjspui%2Fhandle%2F10603%2F53411

http://ir.inflibnet.ac.in:8080/jspui/handle/10603/53411

Rao P. B., A. R. Jain, P. Kishore, P. Balamuralidhar, S. H. Damle, and G. Viswanathan, 1995: Indian MST radar 1. System description and sample vector wind measurements in ST mode. Radio Sci., 30, 1125- 1138.

Ratnam M. V., T. Tsuda, Y. Shibagaki, T. Kozu, and S. Mori, 2006: Gravity wave characteristics over the equator observed during the CPEA campaign using simultaneous data from multiple stations. J. Meteor. Soc.Japan, 84A, 239- 257.10.2151/jmsj.84A.227

8dbafe24-1e27-4b57-a8c4-66c35564e48c

b0a15767da0eed8111ac3959677d0c22

http%3A%2F%2Fci.nii.ac.jp%2Fnaid%2F110004804551%2F

refpaperuri:(318b5d92f01bc6b11890b5efbe3d28d2)

http://ci.nii.ac.jp/naid/110004804551/The vertical and temporal variations of inertia-gravity waves are studied by means of an intensive radiosonde campaign conducted from 10 Apri1 to 9 May, 2004 at five sites, including the Equatorial Atmosphere Radar (EAR) site at Koto Tabang (0.2°S, 100.32°E) in west Sumatra, Indonesia. The four other balloon sounding sites are located about 75-400 km away from EAR. Dominant gravity waves with periods of 2-3 days and vertical wavelengths ofapproximately 3-5 km showing clear downward phase propagation were detected, particularly in the upper troposphere and lower stratosphere (UTLS) region. The gravity wave energy is found to become the largest at an altitude of approximately 20 km, although the enhancement was not continuous, but intermittent. The wave activity was similar at all five sites, having only a slight phase shift, which suggests that the horizontal scale of the wave is larger than the distance between the sites. We have applied a correlative analysis to delineate the horizontal propagation characteristics of gravity waves, and estimated the horizontal wavelength (位h) to be approximately 1,700 km propagating toward 30° south from the east from 26-30 April, 2004, which is further verified by hodograph analysis for individual profiles. From 10-14 April, 2004 and 5-9 May, 2004, 位h and the direction of the propagation were found to be 2,700 km and 3,250 km, and 26° and 3° north from the east, respectively. The spatial and temporal variations in the convection, which is thought to be a major source in the generation of gravity waves, is also studied using satellite data of outgoing long-wave radiation (OLR). We noticed clear eastward advection of large super cloud clusters (SCCs) from the Indian Ocean to the maritime continent, with occasional movement towards the observational sites. The source of the gravity waves is strongly related to this slowly eastward-advecting tropospheric convection, implying that the wave activity observed in the UTLS region was generated by far distant sources located west of the EAR. In addition, we present a case study in which large wave activity did not correspond to the particular cloud convection.

Sato K., 1989: An inertial gravity wave associated with a synoptic-scale pressure trough observed by the MU radar. J. Meteor. Soc.Japan, 67, 325- 333.

Sato K., 1993: Small-scale wind disturbances observed by the MU radar during the passage of typhoon Kelly. J. Atmos. Sci.,50, 518-537, doi: 10.1175/1520-0469(1993)050<0518: SSWDOB>2.0.CO;2.10.1175/1520-0469(1993)050<0518:SSWDOB>2.0.CO;2

48177c9387733578e2b702203cc24ac0

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1993JAtS...50..518S

http://adsabs.harvard.edu/abs/1993JAtS...50..518SThis paper describes small-scale wind disturbances associated with Typhoon Kelly (October 1987) that were observed by the MU radar, one of the MST (mesosphere, stratosphere, and troposphere) radars, continuously for about 60 hours with fine time and height resolution. First, in order to elucidate the background of small-scale disturbances, synoptic-scale variation in atmospheric stability related to the typhoon structure during the observation is examined. When the typhoon passed near the MU radar site, the structure was no longer axisymmetric. There is deep convection only in the front (north-northeast) side of the typhoon while convection behind it is suppressed by a synoptic-scale cold air mass moving eastward to the west of the typhoon. A drastic change in atmospheric stability over the radar site as indicated by echo power profiles is likely due to the passage of the sharp transition zone of convection.Strong small-scale wind disturbances were observed around the typhoon passage. It is shown that the statistical characteristics are significantly different before (BT) and after (AT) the typhoon passage, especially in frequency spectra of vertical wind fluctuations. The spectra for BT are unique compared with earlier studies of vertical winds observed by VHF radars. Another difference is dominance of a horizontal wind component with a vertical wavelength of about 3 km, which is observed only in AT.Further analyses are made of detailed characteristics and vertical momentum fluxes for dominant disturbances. It is found that some of the disturbances are generated so as to remove the momentum of cyclonic wind rotation of the typhoon. Deep convection, topographic effects in strong winds, and strong vertical shear of horizontal winds around an inversion layer are possible sources of the dominant disturbances. Moreover, two monochromatic disturbances lasting for more than 10 h in the lower stratosphere observed in BT and AT, respectively, are identified as inertio-gravity waves, by obtaining wave parameters consistent with all observed quantities. Both of the inertio-gravity waves propagate energy away from the typhoon.

Thomas L., I. T. Prichard, and I. Astin, 1992: Radar observations of an inertia-gravity wave in the troposphere and lower stratosphere. Annales Geophysicae, 10, 690- 697.f53fc4ed7271b130499d6cd2112166df

http%3A%2F%2Fcat.inist.fr%2F%3FaModele%3DafficheN%26cpsidt%3D5544176

http://cat.inist.fr/?aModele=afficheN&cpsidt=5544176

Tsuda T., P. T. May, T. Sato, S. Kato, and S. Fukao, 1988: Simultaneous observations of reflection echoes and refractive index gradient in the troposphere and lower stratosphere. Radio Sci., 23, 655- 665.10.1029/RS023i004p00655

c5cdac0bfce9b1b238ddbb3f246aebae

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2FRS023i004p00655%2Fabstract

http://onlinelibrary.wiley.com/doi/10.1029/RS023i004p00655/abstractWe have studied some characteristics of clear air echoes in the lower stratosphere and troposphere from simultaneous observations of vertical echo power and temperature profiles. The vertical echo power has been oversampled every 75 m with a height resolution of 150 m by the middle and upper atmosphere (MU) radar (35°N, 136°E). During the radar observations a radiosonde was launched at the MU radar site in order to measure temperature, humidity, and pressure with a height resolution of a few tens of meters, from which the mean gradient of generalized potential refractive index, M, was determined. In the lower troposphere (below 10 km altitude), M is enhanced owing to humidity by about 10-20 dB, and its fine structure is mainly determined by the vertical gradient of humidity. The relatively large time-height variation of tropospheric echo power seems to be attributed to rapid changes in the humidity profile. On the other hand, in the upper troposphere (above 10 km altitude) and stratosphere the vertical structure of M is mainly determined by the Brunt-V01is01l01 frequency and air density, where the former determines fine vertical structure of M and the latter the gradual decrease in M with a scale height of about 7 km. The measured Mprofile agrees well with the vertical echo power profile down to the radar height resolution of 150 m. That is, the vertical structure of the reflection coefficient is mainly determined by M, and therefore the energy density of 3-m scale fluctuations E(2k) seems to be distributed uniformly with height. The vertical spacing of intense reflection layers usually ranges from 500 m to a few kilometers, which corresponds to the dominant vertical scale of fluctuations in the Brunt-V01is01l01 frequency profile. The vertical distribution of intense reflection layers seems to be explained by a predominance of a saturated vertical wave number spectrum of gravity waves with a slope of -3 and a dominant vertical scale of a few kilometers.

Tsuda T., Y. Murayama, H. Wiryosumarto, S. W. B. Harijono, and S. Kato, 1994: Radiosonde observations of equatorial atmosphere dynamics over Indonesia: 2. Characteristics of gravity waves. J. Geophys. Res., 99, 10 507- 10 516.10.1029/94JD00354

f145b6cca996dd0874b7079abaf005b0

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F94JD00354%2Fcitedby

http://onlinelibrary.wiley.com/doi/10.1029/94JD00354/citedbyThis paper discusses the characteristics of gravity waves in the equatorial region revealed by analyzing radiosonde measurements of wind velocity and temperature fluctuations at 0–35 km, with a height resolution of 150 m, made every 5–7 hours between February 27 and March 22, 1990, in East Java, Indonesia. We conducted hodograph analysis to delineate vertical and horizontal propagation characteristics and found that most gravity waves were generated in the middle of the troposphere and that they propagated upward into the stratosphere. The amplitudes of wind velocity and temperature fluctuations due to gravity waves were larger in the stratosphere than in the troposphere. The direction of horizontal propagation of gravity waves was rather uniformly distributed in the troposphere, but it became eastward in the lower stratosphere, being opposite to that of the mean winds because of quasi-biennial oscillation. The vertical wavenumber spectra of wind velocity were described fairly well by a saturated model spectrum, although their amplitudes were smaller in the stratosphere. A typical vertical wavelength was 2–2.5 km, while the horizontal phase velocities were 5–7 and 12 m/s in the troposphere and stratosphere, respectively. The amplitudes of small-scale gravity waves were significantly larger in the equatorial stratosphere than at middle latitudes. Time-height variation of the wind velocity variance due to gravity waves showed a clear correlation with that for high relative humidity, which implies that cloud convection is an important mechanism of gravity wave generation in the equatorial region.

VanZand t, T. E., 1982: A universal spectrum of buoyancy waves in the atmosphere. Geophys. Res. Lett., 9, 575- 578.10.1029/GL009i005p00575

beefeddd9a369e56544255a11a5c06a7

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2FGL009i005p00575%2Fcitedby

http://onlinelibrary.wiley.com/doi/10.1029/GL009i005p00575/citedbyCiteSeerX - Scientific documents that cite the following paper: A universal spectrum of buoyancy waves in the atmosphere

Vincent R. A., I. M. Reid, 1983: HF Doppler measurements of mesospheric gravity wave momentum fluxes. J. Atmos. Sci., 40, 1321- 1333.10.1175/1520-0469(1983)040<1321:HDMOMG>2.0.CO;2

59bf2581a0e174d3d202596d0c91d8ec

http%3A%2F%2Fadsabs.harvard.edu%2Fabs%2F1983JAtS...40.1321V

http://adsabs.harvard.edu/abs/1983JAtS...40.1321VThe probable importance of internal gravity waves in balancing the momentum budget of the mesosphere has been emphasized in recent theoretical studies. The present investigation is concerned with a method by which the vertical flux of horizontal momentum can be measured by ground-based radars. The method requires the comparison of the Doppler shifts in backscattered radar echoes from the upper atmosphere using two or more narrow beams offset from the vertical. It is assumed that fluctuations of the Doppler shifts are caused by gravity wave wind oscillations. Provided the atmospheric motions are horizontally homogeneous, the momentum flux is proportional to the difference of the variances of the Doppler velocities. The technique has been applied to observations of the upper mesosphere made with a HF radar located near Adelaide, Australia.

Vincent R. A., M. J. Alexander, 2000: Gravity waves in the tropical lower stratosphere: An observational study of seasonal and interannual variability. J. Geophys. Res., 105, 17 971- 17 982.10.1029/2000JD900196

0cf748b8e93ca3c13b595dc52ee2ffe9

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2000JD900196%2Fcitedby

http://onlinelibrary.wiley.com/doi/10.1029/2000JD900196/citedbyRadiosonde observations made at Cocos Islands (12°S, 97°E) in the Indian Ocean between September 1992 and June 1998 are used to study seasonal and interannual variations in gravity wave activity in the lower stratosphere (18-25 km). The islands are located in a region of generally strong convection that occurs at all times of the year, with the period of strongest convective activity between December and July (wet season). The prevailing zonal winds during the observational period and height range are westward with a quasi-biennial oscillation (QBO) superimposed. Time series of wave energy show that largest wave amplitudes occur during the wet season when convection is strongest, but a QBO-like variation is also apparent. Maximum energy densities of about 25 J kgoccur early 1993, 1995, and 1997 at the times when the westward shears are largest. Wave energy is found to be propagating upward, and in the horizontal there is considerable azimuthal anisotropy, with predominate eastward propagation against the prevailing wind. Upward fluxes of zonal momentum flux (u'w'炉) are estimated by combining the temperature and wind information. Fluxes show a similar temporal behavior to the energy. The motion and temperature fields are dominated by waves with vertical wavelengths 藴2 km. Using a Stokes parameter analysis, it is found that the intrinsic frequencies are, on average, 2-3 times the inertial frequency, corresponding to intrinsic periods of 20-25 hours. Horizontal wavelengths between 200 and 2000 km are inferred, with a mean value of about 1000 km. The mean intrinsic phase speeds are about 10 ms, but ground-based phase speeds are centered on 0 ms.

Worthington R. M., L. Thomas, 1997: Long-period unstable gravity-waves and associated VHF radar echoes. Annales Geophysicae, 15, 813- 822.10.1007/s00585-997-0813-8

a77eb4522d0ce6fab1c00ec775e56ef7

http%3A%2F%2Flink.springer.com%2Farticle%2F10.1007%2Fs00585-997-0813-8

http://link.springer.com/article/10.1007/s00585-997-0813-8VHF atmospheric radar is used to measure the wind velocity and radar echo power related to long-period wind perturbations, including gravity waves, which are observed commonly in the lower stratosphere and tropopause region, and sometimes in the troposphere. These wind structures have been identified previously as either inertia-gravity waves, often associated with jet streams, or mountain waves. At heights of peak wind shear, imbalances are found between the echo powers of a symmetric pair of radar beams, which are expected to be equal. The largest of these power differences are found for conditions of simultaneous high wind shear and high aspect sensitivity. It is suggested that the effect might arise from tilted specular reflectors or anisotropic turbulent scatterers, a result of, for example, Kelvin -Helmholtz instabilities generated by the strong wind shears. This radar power-difference effect could offer information about the onset of saturation in long-period waves, and the formation of thin layers of turbulence.

Zhang F. Q., S. G. Wang, and R. Plougonven, 2004: Uncertainties in using the hodograph method to retrieve gravity wave characteristics from individual soundings. Geophys. Res. Lett., 31,L11110, doi: 10.1029/2004GL019841.10.1029/2004GL019841

75a4f116db8a3702cf2a55b3b3d1e5d6

http%3A%2F%2Fonlinelibrary.wiley.com%2Fdoi%2F10.1029%2F2004GL019841%2Ffull

http://onlinelibrary.wiley.com/doi/10.1029/2004GL019841/fullThe hodograph method is commonly used to retrieve inertio-gravity wave characteristics from individual vertical profiles of the winds. In order to estimate the uncertainties of this method, we have analyzed mesoscale numerical simulations of a gravity wave event in which a coherent quasi-monochromatic inertio-gravity wave packet is present. Single profiles are extracted from the simulations, analyzed using the hodograph method, and the derived wave characteristics are compared to the reference values determined from the four-dimensional simulated fields. Although the conditions favor the use of the hodograph method, the derived wave parameters possess significant uncertainties.

Zong H. J., L. G. Wu, 2015: Re-examination of tropical cyclone formation in monsoon troughs over the western North Pacific. Adv. Atmos. Sci.,32(8), 924-934, doi: 10.1007/ s00376-014-4115-2.10.1007/s00376-014-4115-2

95101c6b03db2875bf49a86dde46967a

http%3A%2F%2Fwww.cnki.com.cn%2FArticle%2FCJFDTOTAL-DQJZ201507004.htm

http://d.wanfangdata.com.cn/Periodical_dqkxjz-e201507004.aspxThe monsoon trough (MT) is one of the large-scale patterns favorable for tropical cyclone (TC) formation over the western North Pacific (WNP). This study re-examines TC formation by treating the MT as a large-scale background for TC activity during May-揙ctober. Over an 11-year (2000-10) period, 8.3 TC formation events on average per year are identified to occur within MTs, accounting for 43.1% of the total TC formation events in the WNP basin. This percentage is much lower than those reported in previous studies. Further analysis indicates that TC formation events in monsoon gyres were included at least in some previous studies. The MT includes a monsoon confluence zone where westerlies meet easterlies and a monsoon shear line where the trade easterlies lie north of the monsoon westerlies. In this study, the large-scale flow pattern associated with TC formation in the MT is composited based on the reference point in the confluence zone where both the zonal and meridional wind components are zero with positive vorticity. While previous studies have found that many TCs form in the confluence zone, the composite analysis indicates that nearly all of the TCs formed in the shear region, since the shear region is associated with stronger low-level relative vorticity than the confluence zone. The prevailing easterly vertical shear of zonal wind and barotropic instability may also be conducive to TC formation in the shear region, through the development of synoptic-scale tropical disturbances in the MT that are necessary for TC formation.