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2. Observational Validation of Parameterized Gravity Waves From Tropical Convection in the Whole Atmosphere Community Climate Model

Author

Albert Hertzog, Julio T. Bacmeister, Chuntao Liu, Jadwiga H. Richter, Martina Bramberger, and M. J. Alexander

Subjects
Convection, Quasi-biennial oscillation, Atmospheric Science, 010504 meteorology & atmospheric sciences, Scale (ratio), Gravitational wave, Parameterized complexity, Atmospheric sciences, 01 natural sciences, Physics::Fluid Dynamics, Atmosphere, Geophysics, 13. Climate action, Space and Planetary Science, Drag, Earth and Planetary Sciences (miscellaneous), Environmental science, Climate model, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences
Abstract

Tropical gravity waves that are generated by convection are generally too small in scale and too high in frequency to be resolved in global climate models, yet their drag forces drive the important...

Published
2021

3. MJO‐Related Intraseasonal Variation in the Stratosphere: Gravity Waves and Zonal Winds

Author

M. J. Alexander, Lars Hoffmann, Claudia Christine Stephan, and Alison W. Grimsdell

Subjects
Atmospheric Science, Gravity (chemistry), 010504 meteorology & atmospheric sciences, Madden–Julian oscillation, 010502 geochemistry & geophysics, 01 natural sciences, Wavelength, Geophysics, Wind profile power law, Space and Planetary Science, Wave drag, Climatology, Physics::Space Physics, ddc:550, Earth and Planetary Sciences (miscellaneous), Astrophysics::Earth and Planetary Astrophysics, Gravity wave, Tropopause, Stratosphere, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences
Abstract

Previous work has shown eastward migrating regions of enhanced temperature variance due to long-vertical wavelength stratospheric gravity waves that are in sync with intraseasonal precipitation and tropopause wind anomalies associated with the Madden-Julian Oscillation (MJO). Here the origin of these intraseasonal gravity wave variations is investigated with a set of idealized gravity wave-resolving model experiments. The experiments specifically test whether tropopause winds act to control gravity wave propagation into the stratosphere by a critical level filtering mechanism or play a role in gravity wave generation through an obstacle source effect. All experiments use identical convective latent heating variability, but the large-scale horizontal wind profile is varied to investigate relationships between stratospheric gravity waves and zonal winds at different levels. Results show that the observed long vertical wavelength gravity waves are primarily sensitive to stratospheric zonal wind variations, while tropopause wind variations have only a very small effect. Thus, neither the critical level filter mechanism nor the obstacle source play much of a role in the observed intraseasonal gravity wave variations. Instead, the results suggest that the stratospheric waves follow the MJO precipitation sources, and tropopause wind anomalies follow the same sources. We further find evidence of intraseasonal wave drag effects on the stratospheric circulation in reanalyzed winds. The results suggest that waves drive intraseasonal stratospheric zonal wind anomalies that descend in altitude with increasing MJO phases 3 through 7. Eastward anomalies descend farther than westward, suggesting that MJO-related stratospheric waves cause larger eastward drag forces.

Published
2018

4. An evaluation of gravity waves and gravity wave sources in the Southern Hemisphere in a 7 km global climate simulation

Author

Lawrence Coy, Chuntao Liu, Laura Holt, Steven Pawson, William M. Putman, M. J. Alexander, and Andrea Molod

Subjects
Physics, Atmospheric Science, 010504 meteorology & atmospheric sciences, Infragravity wave, Geophysics, Internal wave, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Article, Gravity current, Wavelength, Frontogenesis, 13. Climate action, Gravity wave, Radiation stress, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Orographic lift
Abstract

In this study, gravity waves (GWs) in the high-resolution GEOS-5 Nature Run are first evaluated with respect to satellite and other model results. Southern Hemisphere winter sources of non-orographic GWs in the model are then investigated by linking measures of tropospheric non-orographic gravity wave generation tied to precipitation and frontogenesis with absolute gravity wave momentum flux in the lower stratosphere. Finally, non-orographic GW momentum flux is compared to orographic gravity wave momentum flux and compared to previous estimates. The results show that the global patterns in GW amplitude, horizontal wavelength, and propagation direction are realistic compared to observations. However, as in other global models, the amplitudes are weaker and horizontal wavelengths longer than observed. The global patterns in absolute GW momentum flux also agree well with previous model and observational estimates. The evaluation of model non-orographic GW sources in the Southern Hemisphere winter shows that strong intermittent precipitation (greater than 10 mm h−1) is associated with GW momentum flux over the South Pacific, whereas frontogenesis and less intermittent, lower precipitation rates (less than 10 mm h−1) are associated with GW momentum flux near 60°S. In the model, orographic GWs contribute almost exclusively to a peak in zonal mean momentum flux between 70 and 75°S, while non-orographic waves dominate at 60°S, and non-orographic GWs contribute a third to a peak in zonal mean momentum flux between 25 and 30°S.

Published
2017

5. Gravity wave generation by convection and momentum deposition in the mesosphere-lower thermosphere

Author

S. Kovalam, Peter T. May, Robert A. Vincent, B. K. Dolman, Andrew D. MacKinnon, M. J. Alexander, and Iain M. Reid

Subjects
Physics, Atmospheric Science, Mesoscale convective system, Momentum (technical analysis), 010504 meteorology & atmospheric sciences, Wave propagation, Geophysics, Atmospheric sciences, 01 natural sciences, Atmosphere, 13. Climate action, Space and Planetary Science, Latent heat, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Gravity wave, Thermosphere, 010303 astronomy & astrophysics, Stratosphere, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences
Abstract

[1] The Tropical Warm Pool International Cloud Experiment campaign centered on Darwin (12°S, 131°E) in northern Australia in January–February 2006 provided an opportunity to study gravity wave generation by convection and the associated wave propagation and momentum transport. In this study, we discuss wave generation by a single mesoscale convective system (MCS) that occurred on 23 January. The project used a variety of radars to study the spatial and temporal variability of rainfall and the associated latent heat release during the storm. A high-resolution numerical model utilized the latent heat release derived from radar rainfall measurements to compute the spatial and geographic variation of gravity wave generation and propagation into the lower stratosphere. Gravity wave ray-tracing techniques were then used to estimate the wave energy flux penetrating to heights near 90 km, where the results were compared with direct measurements made with a meteor wind radar. This comparison is used to calibrate the momentum fluxes derived from the model and the ray-tracing results using an iterative technique. The momentum was deposited in a relatively compact region. Body forces computed from the flux divergences had their maximum values at heights near 98 km with a peak values of about 400 m s−1h−1. The effects of secondary gravity wave generation are discussed, as is the overall contribution of gravity waves generated by MCSs to the momentum budget of the tropical middle atmosphere.

Published
2013

6. A global view of stratospheric gravity wave hotspots located with Atmospheric Infrared Sounder observations

Author

Xianghui Xue, M. J. Alexander, and Lars Hoffmann

Subjects
Atmospheric Science, Mesoscale meteorology, Atmospheric sciences, Geophysics, Space and Planetary Science, Brightness temperature, Middle latitudes, Atmospheric Infrared Sounder, Earth and Planetary Sciences (miscellaneous), Radiance, Gravity wave, Stratosphere, Geology, Orographic lift
Abstract

[1] The main aim of this study is to find and classify hotspots of stratospheric gravity waves on a global scale. The analysis is based on a 9 year record (2003 to 2011) of radiance measurements by the Atmospheric Infrared Sounder (AIRS) aboard NASA's Aqua satellite. We detect gravity waves based on 4.3 µm brightness temperature variances. Our method focuses on peak events, i.e., strong gravity wave events for which the local variance considerably exceeds background levels. We estimate the occurrence frequencies of these peak events for different seasons and time of day and use the results to find local maxima or “hotspots.” In addition, we use AIRS radiances at 8.1 µm to simultaneously detect convective events, including deep convection in the tropics and mesoscale convective systems at middle latitudes. We classify the gravity wave sources based on seasonal occurrence frequencies for convection, but also by means of time series analyses and topographic data. Our study reproduces well-known hotspots of gravity waves, e.g., the Andes and the Antarctic Peninsula. However, the high horizontal resolution of the AIRS observations also allows us to locate numerous mesoscale hotspots, which are partly unknown or poorly studied so far. Most of these mesoscale hotspots are found near orographic features like mountain ranges, coasts, lakes, deserts, or isolated islands. This study will help to select promising regions and seasons for future case studies of gravity waves.

Published
2013

7. Recent developments in gravity-wave effects in climate models and the global distribution of gravity-wave momentum flux from observations and models

Author

Yoshio Kawatani, Manuel Pulido, Albert Hertzog, Kaoru Sato, Robert A. Vincent, Manfred Ern, Peter Preusse, Tiffany A. Shaw, Saroja Polavarapu, Marvin A. Geller, M. J. Alexander, Stephen D. Eckermann, Michael Sigmond, Charles McLandress, Shingo Watanabe, and Fabrizio Sassi

Subjects
Atmospheric Science, Momentum (technical analysis), 010504 meteorology & atmospheric sciences, Meteorology, Gravitational wave, Atmospheric wave, Momentum transfer, Geophysics, Internal wave, 010502 geochemistry & geophysics, 01 natural sciences, Wavelength, 13. Climate action, Climate model, Gravity wave, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences
Abstract

Recent observational and theoretical studies of the global properties of small-scale atmospheric gravity waves have highlighted the global effects of these waves on the circulation from the surface to the middle atmosphere. The effects of gravity waves on the large-scale circulation have long been treated via parametrizations in both climate and weather-forecasting applications. In these parametrizations, key parameters describe the global distributions of gravity-wave momentum flux, wavelengths and frequencies. Until recently, global observations could not define the required parameters because the waves are small in scale and intermittent in occurrence. Recent satellite and other global datasets with improved resolution, along with innovative analysis methods, are now providing constraints for the parametrizations that can improve the treatment of these waves in climate-prediction models. Research using very-high-resolution global models has also recently demonstrated the capability to resolve gravity waves and their circulation effects, and when tested against observations these models show some very realistic properties. Here we review recent studies on gravity-wave effects in stratosphere-resolving climate models, recent observations and analysis methods that reveal global patterns in gravity-wave momentum fluxes and results of very-high-resolution model studies, and we outline some future research requirements to improve the treatment of these waves in climate simulations. Copyright © 2010 Royal Meteorological Society and Crown in the right of Canada

Published
2010

8. A Model Study of Gravity Waves over Hurricane Humberto (2001)

Author

Eric A. Ray, Michele A. Kuester, and M. J. Alexander

Subjects
Atmospheric Science, Meteorology, Atmospheric wave, Weather forecasting, Mesoscale meteorology, Storm, computer.software_genre, Climatology, MM5, Gravity wave, Tropical cyclone, computer, Stratosphere, Physics::Atmospheric and Oceanic Physics, Geology
Abstract

Atmospheric gravity waves are known to influence global circulations. Understanding these waves and their sources help to develop parameterizations that include their effects in climate and weather forecasting models. Deep convection is believed to be a major source for these waves and hurricanes may be particularly intense sources. Simulations of Hurricane Humberto (2001) are studied using the fifth-generation Pennsylvania State University–National Center for Atmospheric Research (PSU–NCAR) Mesoscale Model (MM5). Humberto is simulated at both tropical storm and hurricane stages. Fourier transform and wavelet analysis are employed to investigate wave characteristics and their behavior in the lower stratosphere. The Fourier analysis gives a regional view of storm affects, whereas wavelet analysis gives a local picture of isolated events. Analysis of the movement of convective sources and local winds gives further insight into the mechanisms that can cause gravity waves. Convectively generated gravity waves are observed in the lower stratosphere of this model with horizontal scales of 15–300 km, vertical scales of 4–8 km, and intrinsic periods of approximately 20–100 min.

Published
2008

9. Formation of large (≃100 μm) ice crystals near the tropical tropopause

Author

T. V. Bui, Darrel Baumgardner, Eric J. Jensen, Elliot M. Weinstock, B. Baker, David S. Sayres, J. A. Smith, Leonhard Pfister, Q. Mo, J. M. St. Clair, Paul Lawson, M. J. Alexander, Elisabeth J. Moyer, Owen B. Toon, Jessica B. Smith, and Thomas F. Hanisco

Subjects
Crystal, Atmosphere, Atmospheric Science, Ice crystals, Chemistry, Ice nucleus, Humidity, Tropopause, Saturation (chemistry), Atmospheric sciences, Water vapor
Abstract

Recent high-altitude aircraft measurements with in situ imaging instruments indicated the presence of relatively large (≃100 μm length), thin (aspect ratios of ≃6:1 or larger) hexagonal plate ice crystals near the tropical tropopause in very low concentrations (3 ppmv). On the other hand, if the crystal aspect ratios are quite a bit larger (≃10:1), then H2O concentrations toward the low end of the measurement range (≃2–2.5 ppmv) would suffice to grow the large crystals. Gravity-wave driven temperature and vertical wind perturbations only slightly modify the H2O concentrations needed to grow the crystals. We find that it would not be possible to grow the large crystals with water concentrations less than 2 ppmv, even with assumptions of a very high aspect ratio of 15 and steady upward motion of 2 cm s−1 to loft the crystals in the tropopause region. These calculations would seem to imply that the measurements indicating water vapor concentrations less than 2 ppmv are implausible, but we cannot rule out the possibility that higher humidity prevailed upstream of the aircraft measurements and the air was dehydrated by the cloud formation. Simulations of the cloud formation with a detailed model indicate that homogeneous freezing should generate ice concentrations larger than the observed concencentrations (20 L−1), and even concentrations as low as 20 L−1 should have depleted the vapor in excess of saturation and prevented growth of large crystals. It seems likely that the large crystals resulted from ice nucleation on effective heterogeneous nuclei at low ice supersaturations. Improvements in our understanding of detailed cloud microphysical processes require resolution of the water vapor measurement discrepancies in these very cold, dry regions of the atmosphere.

Published
2008

10. Intercomparison of stratospheric gravity wave observations with AIRS and IASI

Author

Bernard Tournier, Thomas Rößler, Catrin I. Meyer, Alison W. Grimsdell, Lars Hoffmann, M. J. Alexander, Cathy Clerbaux, Jülich Supercomputing Centre (JSC), Forschungszentrum Jülich GmbH | Centre de recherche de Juliers, Helmholtz-Gemeinschaft = Helmholtz Association-Helmholtz-Gemeinschaft = Helmholtz Association, Colorado Research Associates [Boulder] (CoRA), NorthWest Research Associates (NWRA), TROPO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), NOVELTIS [Sté], and Cardon, Catherine

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Atmospheric circulation, [SDE.MCG]Environmental Sciences/Global Changes, Infrared atmospheric sounding interferometer, 010502 geochemistry & geophysics, 01 natural sciences, [PHYS.PHYS.PHYS-AO-PH] Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph], ddc:550, Gravity wave, lcsh:TA170-171, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Remote sensing, [PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph], Gravitational wave, lcsh:TA715-787, lcsh:Earthwork. Foundations, lcsh:Environmental engineering, 13. Climate action, [SDU.STU.CL]Sciences of the Universe [physics]/Earth Sciences/Climatology, Brightness temperature, Local time, Atmospheric Infrared Sounder, Environmental science, Satellite
Abstract

International audience; Gravity waves are an important driver for the atmospheric circulation and have substantial impact on weather and climate. Satellite instruments offer excellent opportunities to study gravity waves on a global scale. This study focuses on observations from the Atmospheric Infrared Sounder (AIRS) onboard the National Aeronautics and Space Administration's Aqua satellite and the Infrared Atmospheric Sounding Interferometer (IASI) onboard the European MetOp satellites. The main aim of this study is an intercomparison of stratospheric gravity wave observations of both instruments. In particular, we analyzed AIRS and IASI 4.3 μm brightness temperature measurements, which directly relate to stratospheric temperature. Three case studies showed that AIRS and IASI provide a clear and consistent picture of the temporal development of individual gravity wave events. Statistical comparisons based on a five-year period of measurements (2008 - 2012) showed similar spatial and temporal patterns of gravity wave activity. However, the statistical comparisons also revealed systematic differences of variances between AIRS and IASI that we attribute to the different spatial measurement characteristics of both instruments. We also found differences between day- and nighttime data that are partly due to the local time variations of the gravity wave sources. While AIRS has been used successfully in many previous gravity wave studies, IASI data are applied here for the first time for that purpose. Our study shows that gravity wave observations from different hyperspectral infrared sounders such as AIRS and IASI can be directly related to each other, if instrument-specific characteristics such as different noise levels and spatial resolution and sampling are carefully considered. The ability to combine observations from different satellites provides an opportunity to create a long-term record, which is an exciting prospect for future climatological studies of stratospheric gravity wave activity. Reference: Hoffmann, L., Alexander, M. J., Clerbaux, C., Grimsdell, A. W., Meyer, C. I., Rößler, T., and Tournier, B.: Intercomparison of stratospheric gravity wave observations with AIRS and IASI, Atmos. Meas. Tech. Discuss., 7, 8415-8464, doi:10.5194/amtd-7-8415-2014, 2014.

Published
2014

11. A Numerical Study of Three-Dimensional Gravity Waves Triggered by Deep Tropical Convection and Their Role in the Dynamics of the QBO

Author

C. Piani, Dale R. Durran, James R. Holton, and M. J. Alexander

Subjects
Convection, Atmospheric Science, Wavelength, Wind profile power law, Gravitational wave, Mesoscale meteorology, Dynamic pressure, Geophysics, Boundary value problem, Gravity wave, Atmospheric sciences, Physics::Atmospheric and Oceanic Physics, Geology
Abstract

A 3D mesoscale model is used to study the structure of convectively triggered gravity waves in the Tropics and their role in the dynamics of the middle atmosphere. Simulations with three stratospheric background zonal wind cases are examined. In the first case the background wind profile is constant; the other two are representative of the easterly and westerly phases of the quasi-biennial oscillation (QBO). Spectral analysis is used to link the structure of the triggered gravity waves to the dominant vertical wavelength of the latent heating within the convection. In the QBO–wind shear cases, upward propagating gravity waves are damped as they approach their critical layer. The signature of critical-layer absorption is clearly visible in the profiles of vertical momentum-flux divergence. In the simulations with open boundary conditions, the response to vertical momentum-flux divergence takes the form of large dynamic pressure differences between the east and west boundaries together with acceler...

Published
2000

12. A Spectral Parameterization of Mean-Flow Forcing due to Breaking Gravity Waves

Author

T. J. Dunkerton and M. J. Alexander

Subjects
Physics, Momentum, Atmospheric Science, Nonlinear system, Classical mechanics, Gravitational wave, Wind wave, Breaking wave, Equations of motion, Mechanics, Eddy diffusion, Linear stability
Abstract

A spectral parameterization of mean-flow forcing due to breaking gravity waves is described for application in the equations of motion in atmospheric models. The parameterization is based on linear theory and adheres closely to fundamental principles of conservation of wave action flux, linear stability, and wave‐mean-flow interaction. Because the details of wave breakdown and nonlinear interactions are known to be very complex and are still poorly understood, only the simplest possible assumption is made: that the momentum fluxes carried by the waves are deposited locally and entirely at the altitude of linear wave breaking. This simple assumption allows a straightforward mapping of the momentum flux spectrum, input at a specified source altitude, into vertical profiles of mean-flow force. A coefficient of eddy diffusion can also be estimated. The parameterization can be used with any desired input spectrum of momentum flux. The results are sensitive to the details of this spectrum and also realistically sensitive to the background vertical shear and stability profiles. These sensitivities make the parameterization ideally suited for studying both the effects of gravity waves from unique sources like topography and convection as well as generalized broad input spectra. Existing constraints on input parameters are also summarized from the available observations. With these constraints, the parameterization generates realistic variations in gravity-wave-driven, mean-flow forcing.

Published
1999

13. Interpretations of observed climatological patterns in stratospheric gravity wave variance

Author

M. J. Alexander

Subjects
Atmospheric Science, Ecology, Meteorology, Infragravity wave, Wave propagation, Paleontology, Soil Science, Breaking wave, Forestry, Geophysics, Aquatic Science, Internal wave, Oceanography, Space and Planetary Science, Geochemistry and Petrology, Surface wave, Wind wave, Earth and Planetary Sciences (miscellaneous), Gravity wave, Dispersion (water waves), Physics::Atmospheric and Oceanic Physics, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

Observational analyses of gravity waves in the stratosphere have revealed various climatological patterns in gravity wave activity. Seasonal, geographical, and vertical variations have all been observed. In this work, a linear model of gravity wave propagation is applied to investigate the underlying causes of some of the observed patterns. A collection of monochromatic gravity waves that represent a broad spectrum of wavenumbers and frequencies is input at 6-km altitude in the model. Propagation of the waves through realistic background atmospheric wind and stability fields is treated with linear ray theory and a simple saturation condition to limit amplitudes to stable values. The wave spectrum at the 6-km source height is specified to be constant at all latitudes, longitudes, and times, so the variability that appears at higher altitudes is due entirely to background atmosphere variations. Before the model results are compared to the observations, the spectrum of waves is filtered in a way that mimics the limitations of each of the observation techniques. The filtering is described in terms of vertical wavelength and is referred to as the “observational filter.” In a vertically varying background wind, gravity waves are Doppler-shifted in intrinsic frequency and refracted to different vertical wavelengths as they propagate vertically through the atmosphere. The observational filter and the wave refraction effects can thus couple in interesting ways that have not been explicitly considered in previous work. The model shows that this coupling can give rise to geographical, seasonal, and vertical variations in gravity wave observations without any variations in the spectrum or amplitude of gravity wave sources in the troposphere. Thus careful consideration of both the background wind profile and observational filter can greatly affect the interpretation of the observed climatological patterns in gravity wave activity.

Published
1998

14. A Model Study of Zonal Forcing in the Equatorial Stratosphere by Convectively Induced Gravity Waves

Author

M. J. Alexander and James R. Holton

Subjects
Quasi-biennial oscillation, Convection, Atmospheric Science, Atmospheric models, Wave propagation, Physics::Space Physics, Mesoscale meteorology, Atmospheric sciences, Squall line, Stratosphere, Physics::Atmospheric and Oceanic Physics, Geology, Winds aloft
Abstract

A two-dimensional cloud-resolving model is used to examine the possible role of gravity waves generated by a simulated tropical squall line in forcing the quasi-biennial oscillation (QBO) of the zonal winds in the equatorial stratosphere. A simulation with constant background stratospheric winds is compared to simulations with background winds characteristic of the westerly and easterly QBO phases, respectively. In all three cases a broad spectrum of both eastward and westward propagating gravity waves is excited. In the constant background wind case the vertical momentum flux is nearly constant with height in the stratosphere, after correction for waves leaving the model domain. In the easterly and westerly shear cases, however, westward and eastward propagating waves, respectively, are strongly damped as they approach their critical levels, owing to the strongly scale-dependent vertical diffusion in the model. The profiles of zonal forcing induced by this wave damping are similar to profiles given by critical level absorption, but displaced slightly downward. The magnitude of the zonal forcing is of order 5 m s21 day21. It is estimated that if 2% of the area of the Tropics were occupied by storms of similar magnitude, mesoscale gravity waves could provide nearly 1/4 of the zonal forcing required for the QBO.

Published
1997

15. The impact of gravity waves on the Venus thermosphere and O2IR nightglow

Author

S. W. Bougher, M. J. Alexander, and S. Zhang

Subjects
Atmospheric Science, Terminator (solar), Soil Science, Venus, Aquatic Science, Oceanography, Atmospheric sciences, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Gravity wave, Earth-Surface Processes, Water Science and Technology, Physics, Ecology, biology, Gravitational wave, Airglow, Paleontology, Forestry, Geophysics, biology.organism_classification, Space and Planetary Science, Drag, Local time, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Thermosphere
Abstract

The terrestrial Fritts and Lu [1993] gravity wave parameterization, based on the theory of wave saturation, has been adopted within the Venus thermospheric general circulation model (VTGCM) to examine the impact of upward propagating gravity waves on the Venus thermospheric subsolar-to-antisolar (SS-AS) circulation and the resultant O2 IR nightglow. It is shown that the drag force generated by the breakdown of gravity waves can effectively slow down the winds, which results in reproducing the observed day/night contrasts in temperatures and densities. With stronger drag force on the dawn terminator than on the dusk terminator, the apparently superrotating zonal wind can be forced by the dissipation of gravity waves. The equivalent superrotating zonal wind varies both with local time and altitude. The simulated distribution of the O2 IR nightglow is strongly sensitive to small changes of the characteristic intrinsic phase speeds at the model lower boundary. This sensitivity implies that minor variations in gravity wave momentum fluxes to the thermosphere can give rise to large O2 IR emission variations with time and space, in agreement with ground-based observations.

Published
1996

16. Nonstationary gravity wave forcing of the stratospheric zonal mean wind

Author

Karen H. Rosenlof and M. J. Alexander

Subjects
Atmospheric Science, Infragravity wave, Wave propagation, Soil Science, Forcing (mathematics), Aquatic Science, Oceanography, Atmospheric sciences, Physics::Geophysics, Troposphere, Geochemistry and Petrology, Wave drag, Earth and Planetary Sciences (miscellaneous), Gravity wave, Stratosphere, Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Physics, Ecology, Paleontology, Forestry, Geophysics, Space and Planetary Science, Climatology, Phase velocity
Abstract

The role of gravity wave forcing in the zonal mean circulation of the stratosphere is discussed. Starting from some very simple assumptions about the momentum flux spectrum of nonstationary (non-zero phase speed) waves at forcing levels in the troposphere, a linear model is used to calculate wave propagation through climatological zonal mean winds at solstice seasons. As the wave amplitudes exceed their stable limits, a saturation criterion is imposed to account for nonlinear wave breakdown effects, and the resulting vertical gradient in the wave momentum flux is then used to estimate the mean flow forcing per unit mass. Evidence from global, assimilated data sets are used to constrain these forcing estimates. The results suggest the gravity-wave-driven force is accelerative (has the same sign as the mean wind) throughout most of the stratosphere above 20 km. The sense of the gravity wave forcing in the stratosphere is thus opposite to that in the mesosphere, where gravity wave drag is widely believed to play a principal role in decelerating the mesospheric jets. The forcing estimates are further compared to existing gravity wave parameterizations for the same climatological zonal mean conditions. Substantial disagreement is evident in the stratosphere, and we discuss the reasons for the disagreement. The results suggest limits on typical gravity wave amplitudes near source levels in the troposphere at solstice seasons. The gravity wave forcing in the stratosphere appears to have a substantial effect on lower stratospheric temperatures during southern hemisphere summer and thus may be relevant to climate.

Published
1996

17. High Resolution Dynamics Limb Sounder observations of the gravity wave-driven elevated stratopause in 2006

Author

John C. Gille, V. L. Harvey, Cora E. Randall, and M. J. Alexander

Subjects
Atmospheric Science, Ecology, Meteorology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Mesosphere, Atmosphere, Microwave Limb Sounder, Depth sounding, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Stratopause, Earth and Planetary Sciences (miscellaneous), Environmental science, Radiometry, Satellite, Gravity wave, Earth-Surface Processes, Water Science and Technology
Abstract

[1] Temperature observations during January and February 2006 from the High Resolution Dynamics Limb Sounder (HIRDLS), the Microwave Limb Sounder (MLS), and the Sounding of the Atmosphere using Broadband Emission Radiometry (SABER) satellite instruments are compared to illustrate the vertical range over which version 6 HIRDLS temperatures are scientifically useful. In order to determine the quality of HIRDLS temperatures in the middle atmosphere, we compare the height and temperature of the HIRDLS stratopause with MLS and SABER before, during, and after the 2006 major stratospheric sudden warming. Results show that HIRDLS observes the elevated stratopause at 78 km two days later than MLS and five days after SABER. We compare the geographical temperature structure of these data sets at 0.01 hPa during this period. Though HIRDLS temperatures are consistently 5–10 K lower in the mesosphere, this is the first study to show that the horizontal temperature distribution is in good spatial and temporal agreement with MLS and SABER up to ∼80 km. Gravity wave momentum flux and planetary wave 1 amplitudes are derived from HIRDLS and shown to be in agreement with previous studies. We use HIRDLS to show a ∼30 K increase in stratopause temperature following enhanced gravity wave momentum flux in the lower mesosphere.

Published
2012

18. Equatorial waves in High Resolution Dynamics Limb Sounder (HIRDLS) data

Author

D. A. Ortland and M. J. Alexander

Subjects
Atmospheric Science, Soil Science, Aquatic Science, Oceanography, Atmospheric sciences, Troposphere, symbols.namesake, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Wavenumber, Stratosphere, Physics::Atmospheric and Oceanic Physics, Equatorial Rossby wave, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Equatorial waves, Forestry, Wavelength, Geophysics, Space and Planetary Science, symbols, Tropopause, Kelvin wave, Geology
Abstract

[1] We examine equatorial wave structure in temperature measurements from the High Resolution Dynamics Limb Sounder (HIRDLS) on the Aura satellite. Waves with periods longer than 1 day and zonal wave numbers up to 8 (depending on frequency) are derived from an asynoptic Fourier transform analysis. HIRDLS measurement sampling and resolution afford unprecedented views of the latitude-height structure of equatorial Rossby wave, mixed Rossby-gravity wave, and Kelvin wave modes at altitudes above cloud tops in the tropical upper troposphere and stratosphere. Wave modes with vertical wavelength as short as 4 km can be clearly seen in the data. Kelvin waves comprise a dominant signal throughout the 3 years of HIRDLS measurements, and we further examine time, height, and longitude variations observed in the Kelvin waves. An annual cycle of Kelvin wave temperature amplitudes near the tropopause is observed that may have implications for annual variations in wave-cirrus formation in the tropics. This annual variation can be largely explained by effects of the background wind and stability on Kelvin wave propagation and potential energy in the tropical tropopause layer. At altitudes 20 km and above, the annual cycle gives way to an interannual cycle in Kelvin wave amplitudes that is related to the quasi-biennial oscillation in stratospheric winds. This interannual variation is a signature of Kelvin wave forcing of the descent of westerly winds in the oscillation, and we compute the Kelvin wave fractional contribution to the forcing.

Published
2010

19. Global estimates of gravity wave parameters from GPS radio occultation temperature data

Author

L. Wang and M. J. Alexander

Subjects
Atmospheric Science, Equator, Soil Science, Aquatic Science, Oceanography, law.invention, Troposphere, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Radio occultation, Gravity wave, Stratosphere, Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Ecology, business.industry, Paleontology, Forestry, Geophysics, Space and Planetary Science, Radiosonde, Global Positioning System, Ionosphere, business, Geology
Abstract

[1] Gravity waves (GWs) play critical roles in the global circulation and the temperature and constituent structures in the middle atmosphere. They also play significant roles in the dynamics and transport and mixing processes in the upper troposphere and lower stratosphere and can affect tropospheric weather. Despite significant advances in our understanding of GWS and their effects in different regions of the atmosphere in the past few decades, observational constraints on GW parameters including momentum flux and propagation direction are still sorely lacking. Global Positioning System (GPS) radio occultation (RO) technique provides global, all-weather, high vertical resolution temperature profiles in the stratosphere and troposphere. The unprecedentedly large number of combined temperature soundings from the Constellation Observing System for Meteorology, Ionosphere, and Climate and Challenging Minisatellite Payload GPS RO missions allows us to obtain GW perturbations by removing the gravest zonal modes using the wavelet method for each day. We extended the GW analysis method of Alexander et al. (2008) to three dimensions to estimate the complete set of GW parameters (including momentum flux and horizontal propagation direction) from the GW temperature perturbations thus derived. To demonstrate the effectiveness of the analysis, we showed global estimates of GW temperature amplitudes, vertical and horizontal wavelengths, intrinsic frequency, and vertical flux of horizontal momentum in the altitude range of 17.5–22.5 km during December 2006 to February 2007. Consistent with many previous studies, GW temperature amplitudes are a maximum in the tropics and are generally larger over land, likely reflecting convection and topography as main GW sources. GW vertical wavelengths are a minimum at equator, likely due to wave refraction, whereas GW horizontal wavelengths are generally longer in the tropics. Most of the waves captured in the analysis of the GPS data are low-intrinsic frequency inertia-GWs, and the estimated intrinsic frequencies scaled by the Coriolis parameter also show a strong maximum at equator. Enhanced wave fluxes are linked to convection, topography, and storm tracks, among others. As preliminary tests of the analysis in deriving horizontal propagation directions, we compared the GPS estimates with the corresponding estimates from the U.S. high vertical resolution radiosonde data using the conventional Stokes parameters method and we also conducted a separate analysis of the GPS data over the southern Andes in South America. We also showed the first global estimates of GW propagation directions from the GPS data. Finally, the sensitivity of the analysis to the temporal and spatial dimensions of the longitude × latitude × time cells and the uncertainties of the analysis and possible ways to reduce these uncertainties are discussed.

Published
2010

20. Occurrence frequency of convective gravity waves during the North American thunderstorm season

Author

Lars Hoffmann and M. J. Alexander

Subjects
Convection, Atmospheric Science, Meteorology, Soil Science, Aquatic Science, Oceanography, Geochemistry and Petrology, ddc:550, Earth and Planetary Sciences (miscellaneous), Gravity wave, Stratosphere, Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Ecology, Paleontology, Forestry, Wavelength, Geophysics, Space and Planetary Science, Brightness temperature, Climatology, Middle latitudes, Atmospheric Infrared Sounder, Thunderstorm, Geology
Abstract

[1] Convective gravity waves are an important driver of the equator-to-pole circulation in the stratospheric summer hemisphere, but their nature is not well known. Previous studies showing tight relationships between deep convection and convective waves mainly focus on tropical latitudes. For midlatitudes most analyses are based on case studies. Here we present a new multiyear occurrence frequency analysis of convective waves at midlatitudes. The study is based on radiance measurements made by the Atmospheric Infrared Sounder (AIRS) satellite experiment during the North American thunderstorm season, May to August, in the years 2003–2008. For this study we optimized an existing algorithm to detect deep convection in AIRS data to be applicable at midlatitudes. We also present a new detection algorithm for gravity waves in AIRS data based on a variance filter approach for 4.3 μm brightness temperatures. The new algorithm can detect plane wave perturbations in the altitude range from 20 to 65 km with vertical wavelengths larger than 15 km and horizontal wavelengths from 50 to 1000 km. By analyzing spatial and temporal correlations of the individual AIRS observations, it can be shown that more than 95% of the observed gravity waves in a core region over the North American Great Plains are related to deep convective clouds, i.e., are likely being classified appropriately as convective waves. We conclude that the core region is a good location to observe and characterize the properties of convective waves at midlatitudes. The statistical analyses presented here are also valuable to validate parameterization schemes for convective gravity waves. For completeness, it should be mentioned that our analyses cover not only the U.S. Midwest but the North American continent as well as the surrounding ocean regions in general. Our analysis also reveals interesting details about tropical convection and related gravity wave activity, as well as the capability of the AIRS instrument to observe these.

Published
2010

21. Imaging of atmospheric gravity waves in the stratosphere and upper mesosphere using satellite and ground-based observations over Australia during the TWPICE campaign

Author

Peter T. May, Andrew D. MacKinnon, L. J. Gelinas, J. Woithe, James M. Russell, Martin G. Mlynczak, M. J. Alexander, James H. Hecht, Wilbert R. Skinner, Robert A. Vincent, and Richard L. Walterscheid

Subjects
Atmospheric Science, Ecology, Airglow, Paleontology, Soil Science, Forestry, Storm, Geophysics, Aquatic Science, Oceanography, Atmospheric sciences, Wavelength, Altitude, Space and Planetary Science, Geochemistry and Petrology, Atmospheric Infrared Sounder, Earth and Planetary Sciences (miscellaneous), Atmospheric duct, Gravity wave, Stratosphere, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] During the Tropical Warm Pool International Cloud Experiment (TWPICE) an intense tropical low was situated between Darwin and Alice Springs, Australia. Observations made on 31 January 2006 by the Atmospheric Infrared Sounder instrument on the NASA Aqua satellite imaged the presence of atmospheric gravity waves (AGWs), at approximately 40 km altitude, with horizontal wavelengths between 200 and 400 km that were originating from the region of the storm. Airglow images obtained from Alice Springs (about 600 km from the center of the low) showed the presence of similar waves with observed periods of 1 to 2 h. The images also revealed the presence of 30- to 45-km-horizontal-wavelength AGWs with shorter observed periods of near 15 to 25 min. Ray tracing calculations show that (1) some of the long wavelength waves traveled on rays, without ducting, to the altitudes where the observations were obtained, and (2) shorter-period waves rapidly reached 85 km altitude at a horizontal distance close to the storm, thus occurring over Alice Springs only if they were trapped or ducted. The mesospheric inversion layer seen in the measured temperature data almost forms such a trapped region. The winds therefore critically control the formation of the trapped region. Wind profiles deduced from the available data show the plausibility for the formation of such a trapped region. Variations in the wind, however, would make ideal trapped region conditions short-lived, and this may account for the sporadic nature of the short-period wave observations.

Published
2009

22. Retrieval of stratospheric temperatures from Atmospheric Infrared Sounder radiance measurements for gravity wave studies

Author

Lars Hoffmann and M. J. Alexander

Subjects
Atmospheric Science, Ecology, Meteorology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Temperature measurement, Wavelength, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Atmospheric Infrared Sounder, Earth and Planetary Sciences (miscellaneous), Nadir, Radiance, Environmental science, Satellite, Gravity wave, Stratosphere, Earth-Surface Processes, Water Science and Technology, Remote sensing
Abstract

[1] The Atmospheric Infrared Sounder (AIRS) on board the National Aeronautics and Space Administration's (NASA's) Aqua satellite has been continuously measuring mid-infrared nadir and sub-limb radiance spectra since summer of 2002. These measurements are utilized to retrieve three-dimensional stratospheric temperature distributions by applying a new fast forward model for AIRS and an accompanying optimal estimation retrieval processor. The retrieval scheme presented in this article does not require simultaneous observations of microwave instruments like the AIRS operational analyses. Instead, independent retrievals are carried out at the full horizontal sampling capacity of the instrument. Horizontal resolution is enhanced by a factor 3 in along- and across-track directions compared with the AIRS operational data. The total retrieval error of the individual temperature measurements is 1.6 to 3.0 K in the altitude range from 20 to 60 km. Retrieval noise is 1.4 to 2.1 K in the same vertical range. Contribution of a priori information to the retrieval results is less than 1% to 2% and the vertical resolution of the observations is about 7 to 15 km. The temperature measurements are successfully compared with ECMWF operational analyses and AIRS operational Level 2 data. The new temperature data set is well suited for studies of stratospheric gravity waves. We present AIRS observations of small-scale gravity waves induced by deep convection near Darwin, Australia, in January 2003. A strong mountain wave event over the Andes in June 2005 is analyzed in detail. Temperature perturbations derived from the new data set are compared with results from the AIRS operational Level 2 data and coincident measurements of the High Resolution Dynamics Limb Sounder (HIRDLS). The new retrieval does not show response to wave perturbations if the vertical wavelength is below 10 km. For 15 km vertical wavelength, the amplitudes are damped by a factor of two. For vertical wavelengths of greater than 20 km, AIRS shows very similar wave structure to HIRDLS and also has the advantage of providing horizontal phase front information. Data from the new full-resolution retrieval are far more suitable for gravity wave studies than results from the AIRS operational analysis.

Published
2009

23. Intermediate-scale tropical inertia gravity waves observed during the TWP-ICE campaign

Author

M. J. Alexander and Stephanie Evan

Subjects
Atmospheric Science, Infragravity wave, Soil Science, Aquatic Science, Oceanography, law.invention, symbols.namesake, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Gravity wave, Stratosphere, Physics::Atmospheric and Oceanic Physics, Earth-Surface Processes, Water Science and Technology, Quasi-biennial oscillation, Physics, Ecology, Paleontology, Forestry, Geophysics, Internal wave, Geodesy, Wavelength, Space and Planetary Science, symbols, Radiosonde, Kelvin wave
Abstract

[1] We describe a 2-day wave event observed in high-resolution radiosonde soundings of horizontal wind and temperature taken during the TWP-ICE experiment in Darwin area. The vertical profiles of temperature, zonal and meridional wind speeds are analyzed using the S-transform wavelet analysis. Results of the analysis reveal the presence of 2-day inertia gravity waves in the stratosphere between 20 and 27 km. The wave presents vertical and horizontal wavelengths of around 6 km and 7220 km respectively. The wave was observed to propagate southeastward during the end of the easterly phase of the QBO. The total vertical momentum flux associated with the waves is estimated to be 1 to 2.2 × 10−3 m2s−2. This is of the same order of magnitude as previous observations of 4–10 day Kelvin waves in the lower stratosphere.

Published
2008

24. Global observations of HNO3from the High Resolution Dynamics Limb Sounder (HIRDLS): First results

Author

Valery Yudin, V. Dean, Hanna Lee, B. Mankin, C. D. Boone, D. Ellis, David W. Fahey, T. Eden, John J. Barnett, Gene Francis, C. Craig, James W. Hannigan, Cora E. Randall, P. J. Popp, M. J. Alexander, Peter F. Bernath, Doug Kinnison, C. Krinsky, Daniel Packman, Alyn Lambert, Christopher L. Hepplewhite, Kaley A. Walker, B. Nardi, R. Khosravi, M. T. Coffey, C. Halvorson, S. Massie, T. P. Marcy, C. Cavanaugh, C. Hartsough, Michelle L. Santee, John C. Gille, and V. L. Harvey

Subjects
Atmospheric Science, Ecology, Instrumentation, Paleontology, Soil Science, High resolution, Forestry, Aquatic Science, Oceanography, Atmospheric sciences, Latitude, Microwave Limb Sounder, Geophysics, Altitude, Space and Planetary Science, Geochemistry and Petrology, Atmospheric chemistry, Earth and Planetary Sciences (miscellaneous), Environmental science, Satellite, Stratosphere, Earth-Surface Processes, Water Science and Technology, Remote sensing
Abstract

[1] We present the first evaluation of the HNO3 data product (version 2.04.09) from the High Resolution Dynamics Limb Sounder (HIRDLS) on the Earth Observing System (EOS) Aura satellite. The HIRDLS instrument obtains between 5000 and 7000 HNO3 profiles per day. HIRDLS HNO3 data are generally good over the latitude range of 64°S to 80°N and pressure range 100 to 10 hPa, with some profiles, depending on latitude, having useful information between 100 to 161 hPa. The individual profile “measured” precision is between 10 and 15%, but can be much larger if the HNO3 abundance is low or outside the 100 hPa to 10 hPa range. Global results are compared with the HNO3 observations from version 2.2 of the EOS Aura Microwave Limb Sounder (MLS), and it is found that large-scale features are consistent between the two instruments. HIRDLS HNO3 is biased 0–20% low relative to Aura MLS in the mid-to-high latitudes and biased high in the tropical stratosphere. HIRDLS HNO3 is also compared with Atmospheric Chemistry Experiment Fourier Transform Spectrometer (ACE-FTS). In these mostly high-latitude comparisons the HIRDLS HNO3 data are biased 10–30% low, depending on altitude. Finally, the HIRDLS HNO3 is compared to in situ data taken by the NOAA Chemical Ionization Mass Spectrometer (CIMS) instrument flown during the 2005 NASA Houston Aura Validation Experiment (AVE) and the ability of HIRDLS to measure HNO3 in the UTLS region is examined.

Published
2008

25. Global estimates of gravity wave momentum flux from High Resolution Dynamics Limb Sounder observations

Author

M. J. Alexander, James W. Hannigan, Gene Francis, C. Craig, T. Eden, John J. Barnett, Steven T. Massie, V. Dean, R. Khosravi, Hanna Lee, Christopher L. Hepplewhite, B. Nardi, Douglas E. Kinnison, C. Halvorson, Alyn Lambert, M. T. Coffey, C. Cavanaugh, and John C. Gille

Subjects
Atmospheric Science, Ecology, Meteorology, Momentum transfer, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Geodesy, Wavelength, Geophysics, Amplitude, Space and Planetary Science, Geochemistry and Petrology, Wave shoaling, Earth and Planetary Sciences (miscellaneous), Wavenumber, Mean flow, Gravity wave, Significant wave height, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

analyzed to derive global properties of gravity waves. We describe a wavelet analysis technique that determines covarying wave temperature amplitude in adjacent temperature profile pairs, the wave vertical wavelength as a function of height, and the horizontal wave number along the line joining each profile pair. The analysis allows a local estimate of the magnitude of gravity wave momentum flux as a function of geographic location and height on a daily basis. We examine global distributions of these gravity wave properties in the monthly mean and on an individual day, and we also show sample instantaneous wave events observed by HIRDLS. The results are discussed in terms of previous satellite and radiosonde observational analyses and middle atmosphere general circulation model studies that parameterize gravity wave effects on the mean flow. The high vertical and horizontal resolution afforded by the HIRDLS measurements allows the analysis of a wider range of wave vertical and horizontal wavelengths than previous studies and begins to show individual wave events associated with mountains and convection in high detail. Mountain wave observations show clear propagation to altitudes in the mesosphere.

Published
2008

26. Small-scale gravity waves in ER-2 MMS/MTP wind and temperature measurements during CRYSTAL-FACE

Author

T. B. Bui, L. Wang, M. J. Alexander, Michael J. Mahoney, EGU, Publication, Colorado Research Associates [Boulder] (CoRA), NorthWest Research Associates (NWRA), NASA Ames Research Center (ARC), Jet Propulsion Laboratory (JPL), and NASA-California Institute of Technology (CALTECH)

Subjects
[SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Atmospheric Science, Momentum (technical analysis), Flight level, 010504 meteorology & atmospheric sciences, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, 010502 geochemistry & geophysics, Atmospheric sciences, Atmospheric temperature, Geodesy, 01 natural sciences, lcsh:QC1-999, Troposphere, lcsh:Chemistry, Temperature gradient, Wavelength, lcsh:QD1-999, Dispersion relation, Stratosphere, Geology, Physics::Atmospheric and Oceanic Physics, lcsh:Physics, 0105 earth and related environmental sciences
Abstract

Lower stratospheric wind and temperature measurements made from NASA's high-altitude ER-2 research aircraft during the CRYSTAL-FACE campaign in July 2002 were analyzed to retrieve information on small scale gravity waves (GWs) at the aircraft's flight level (typically ~20 km altitude). For a given flight segment, the S-transform (a Gaussian wavelet transform) was used to search for and identify small horizontal scale GW events, and to estimate their apparent horizontal wavelengths. The horizontal propagation directions of the events were determined using the Stokes parameter method combined with the cross S-transform analysis. The vertical temperature gradient was used to determine the vertical wavelengths of the events. GW momentum fluxes were calculated from the cross S-transform. Other wave parameters such as intrinsic frequencies were calculated using the GW dispersion relation. More than 100GW events were identified. They were generally high frequency waves with vertical wavelength of ~5 km and horizontal wavelength generally shorter than 20 km. Their intrinsic propagation directions were predominantly toward the east, whereas their ground-based propagation directions were primarily toward the west. Among the events, ~20% of them had very short horizontal wavelength, very high intrinsic frequency, and relatively small momentum fluxes, and thus they were likely trapped in the lower stratosphere. Using the estimated GW parameters and the background winds and stabilities from the NCAR/NCEP reanalysis data, we were able to trace the sources of the events using a simple reverse ray-tracing. More than 70% of the events were traced back to convective sources in the troposphere, and the sources were generally located upstream of the locations of the events observed at the aircraft level. Finally, a probability density function of the reversible cooling rate due to GWs was obtained in this study, which may be useful for cirrus cloud models.

Published
2006

27. Seasonal cycle of orographic gravity wave occurrence above small islands in the Southern Hemisphere: Implications for effects on the general circulation

Author

M. J. Alexander and A. W. Grimsdell

Subjects
Atmospheric Science, Atmospheric wave, Atmospheric sciences, Physics::Geophysics, Latitude, Geophysics, Prevailing winds, Space and Planetary Science, Climatology, Atmospheric Infrared Sounder, Earth and Planetary Sciences (miscellaneous), Astrophysics::Earth and Planetary Astrophysics, Gravity wave, Southern Hemisphere, Stratosphere, Physics::Atmospheric and Oceanic Physics, Geology, Orographic lift
Abstract

[1] Orographic gravity waves generated by flow over the topography of small islands in the southern oceans have been observed from orbit with the Atmospheric Infrared Sounder on the Aqua satellite. We examine the occurrence frequencies of these waves in the stratosphere at ∼40km above 14 islands and examine geographical and seasonal changes. Our results show that these small island mountain waves occur commonly in the stratosphere in the May–September season, though not every day. Differing seasonal variations are evident at different islands, and the seasonal variations are closely related to latitude and prevailing wind patterns. We also examine interannual variability in 2years of data and the relationships between occurrence frequencies, momentum fluxes, and stratospheric and surface winds. The results suggest that stratospheric winds have a first-order limiting effect on the observations of these island mountain waves in Atmospheric Infrared Sounder (AIRS) data. Surface wind direction and island orographic relief have an additional but secondary influence on the island mountain wave occurrence frequencies in AIRS data. The implications are that these wave events are extremely common and that on many days when the waves are not observed in AIRS data they have likely dissipated and induced a drag force on the atmosphere below the 40km observation level. Observations of momentum flux during these wave events also permit a first estimate of their importance to the general circulation of the Southern Hemisphere.

Published
2013

28. VHF profiler observations of winds and waves in the troposphere during the Darwin Area Wave Experiment (DAWEX)

Author

Robert A. Vincent, Andrew D. MacKinnon, M. J. Alexander, and Iain M. Reid

Subjects
Convection, Atmospheric Science, Ecology, Paleontology, Soil Science, Forestry, Aquatic Science, Oceanography, Monsoon, Wind profiler, Atmospheric sciences, Troposphere, Geophysics, Space and Planetary Science, Geochemistry and Petrology, Diurnal cycle, Climatology, Zonal flow, Convective storm detection, Earth and Planetary Sciences (miscellaneous), Gravity wave, Geology, Earth-Surface Processes, Water Science and Technology
Abstract

[1] A VHF atmospheric radar (wind profiler) was used to study tropospheric winds during the Darwin Area Wave Experiment (DAWEX). The profiler, which operated at a frequency of 54.1 MHz, was located at Pirlangimpi (Garden Point) (11.4°S, 130.5°E) on the Tiwi Islands. Observations were made regularly up to heights near 8 km, with maximum heights occurring when convective activity was strongest. Mean winds observed between October and December 2001 are in good agreement with conditions that prevailed across northern Australia during this period. During the first two intensive observation periods (IOP) during October and November, the zonal and meridional wind components were westward and northward, respectively, with stronger values in November. By the time of IOP3 in mid-December, the zonal flow was eastward, a pattern that is typical of the Australian monsoon. Fluctuations in the three wind components for periods less than 3 hours are analyzed for IOP2 in November, when strong convective storms (“Hectors”) occurred on all afternoons over the Tiwi Islands. The fluctuations, which are ascribed to convectively generated gravity waves, show a correspondingly strong diurnal cycle, with horizontal wind variances peaking between 8 and 12 m2s−2 in the early afternoon in the lower troposphere. Variances are only ∼2 m2s−2 in the early morning hours. A power spectral analysis shows that oscillations with ground-based periods between 8 and 17 min are especially prominent during Hector events. The profiler observations are compared with a numerical model study of gravity wave generation by convection on 17 November 2001. There is a satisfactory degree of agreement between the behavior of the model and profiler oscillations, both as a function of height and time.

Published
2004

29. On the spectrum of vertically propagating gravity waves generated by a transient heat source

Author

M. J. Alexander, J. R. Holton, EGU, Publication, Colorado Research Associates [Boulder] (CoRA), NorthWest Research Associates (NWRA), Department of Atmospheric Sciences [Seattle], and University of Washington [Seattle]

Subjects
Convection, Atmospheric Science, 010504 meteorology & atmospheric sciences, Infragravity wave, 0207 environmental engineering, 02 engineering and technology, 01 natural sciences, lcsh:Chemistry, 0103 physical sciences, Gravity wave, Dispersion (water waves), 020701 environmental engineering, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, [SDU.OCEAN]Sciences of the Universe [physics]/Ocean, Atmosphere, Physics, [SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, Geophysics, Internal wave, lcsh:QC1-999, Computational physics, Wavelength, lcsh:QD1-999, Surface wave, 13. Climate action, Mechanical wave, lcsh:Physics
Abstract

It is commonly believed that cumulus convection preferentially generates gravity waves with tropospheric vertical wavelengths approximately twice the depth of the convective heating. Individual cumulonimbus, however, act as short term transient heat sources (duration 10 to 30 min). Gravity waves generated by such sources have broad frequency spectra and a wide range of vertical scales. The high-frequency components tend to have vertical wavelengths much greater than twice the depth of the heating. Such waves have large vertical group velocities, and are only observed for a short duration and at short horizontal distances from the convective source. At longer times and longer distances from the source the dominant wave components have short vertical wavelengths and much slower group velocities, and thus are more likely to be observed even though their contribution to the momentum flux in the upper stratosphere and mesosphere may be less than that of the high frequency waves. These properties of convectively generated waves are illustrated by a linear numerical model for the wave response to a specified transient heat source. The wave characteristics are documented through Fourier and Wavelet analysis, and implications for observing systems are discussed.

Published
2004

30. Local time asymmetries in the Venus thermosphere

Author

S. W. Boucher, A. I. F. Stewart, Stanley C. Solomon, and M. J. Alexander

Subjects
Atmospheric Science, Terminator (solar), Soil Science, Venus, Astrophysics, Aquatic Science, Oceanography, Atmospheric sciences, law.invention, Atmosphere of Venus, Atmosphere, Orbiter, Geochemistry and Petrology, law, Earth and Planetary Sciences (miscellaneous), Radiative transfer, Earth-Surface Processes, Water Science and Technology, Physics, Ecology, biology, Paleontology, Forestry, biology.organism_classification, Geophysics, Space and Planetary Science, Local time, Thermosphere
Abstract

A comparison is presented of the 130-m images taken in the Venus thermosphere by the Pioneer Venus Orbiter Ultraviolet Spectrometer (PVOUVS) to predictions by a model which incorporates current understanding of the global structure of the thermosphere, the mechanisms which excite the 130-nm transition in O, and the radiative transport of the 130-nm triplet in the thermosphere. The features identified in the data/model comparison appear as a local time asymmetry in B(130) and O at altitudes poleward of 30 deg. Oxygen densities at the evening terminator are typically a factor of 2 higher than those at the morning terminator. This asymmetry in O has never before been observed or predicted in the global thermospheric models.

Published
1993

31. Atomic oxygen in the Martian thermosphere

Author

A. I. F. Stewart, M. J. Alexander, Larry J. Paxton, Stephen W. Bougher, C. G. Fesen, and R. R. Meier

Subjects
Physics, Martian, Atmospheric Science, Ecology, Airglow, Paleontology, Soil Science, Forestry, Atmosphere of Mars, Mars Exploration Program, Aquatic Science, Oceanography, Atmospheric temperature, Atmospheric sciences, Geophysics, Atmosphere of Earth, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Radiative transfer, Thermosphere, Earth-Surface Processes, Water Science and Technology
Abstract

Modern models of thermospheric composition and temperature and of excitation and radiative transfer processes are used to simulate the O I 130-nm emission from Mars measured by the Mariner 9 ultraviolet spectrometer. This paper uses the Mars thermospheric general circulation model calculations (MTGCM) of Bougher et al. (1988) and the Monte Carlo partial frequency redistribution multiple scattering code of Meier and Lee (1982). It is found that the decline in atomic oxygen through the daylight hours predicted by the MTGCM cannot be reconciled with the excess afternoon brightness seen in the data. Oxygen concentrations inferred from the data show a positive gradient through the day, in agreement with the original analysis by Strickland et al. (1973). In addition, the data suggest that the oxygen abundance increases toward high southerly latitudes, in contrast with the MTGCM prediction of high values in the Northern Hemisphere. It appears that solar forcing alone cannot account for the observed characteristics of the Martian thermosphere and that wave and tidal effects may profoundly affect the structure, winds, and composition.

Published
1992

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