Affiliation:
1. Институт радиотехники и электроники им. В.А. Котельникова РАН
2. Kotel’nikov Institute of Radio Engineering and Electronics RAS
Abstract
Internal gravity waves (IGW) significantly affect the structure and circulation of Earth’s atmosphere by transporting wave energy and momentum upward from the lower atmosphere. Since IGW can propagate freely through a stably stratified atmosphere, similar effects may occur in the atmospheres of Mars and Venus. Observations of temperature and wind speed fluctuations induced by internal waves in Earth’s atmosphere have shown that wave amplitudes increase with height, but not quickly enough to correspond to the amplitude increase due to an exponential decrease in the density without energy dissipation. The linear theory of IGW explains the wave amplitude growth rate as follows: any wave amplitude exceeding the threshold value leads to instability and produces turbulence, which hinders further amplitude growth (internal wave saturation). The mechanisms that contribute most to the energy dissipation and saturation of IGW in the atmosphere are thought to be the dynamical (shear) and convective instabilities. The assumption of internal wave saturation plays a key role in radio occultation (RO) monitoring of IGW in planetary atmospheres. A radiosonde study of wave saturation processes in Earth’s atmosphere is therefore actual and important task. We report the results of determination of actual and threshold amplitudes, saturation degree, and other characteristics for the identified IGW in Earth’s atmosphere obtained from the analysis of SPARC (Stratospheric Processes And their Role in Climate) radiosonde measurements of wind speed and temperature [http://www.sparc.sunysb.edu/].
Publisher
Infra-M Academic Publishing House
Subject
Space and Planetary Science,Atmospheric Science,Geophysics
Reference38 articles.
1. Гаврилов Н.М., Мануйлова Р.О. Многолетние глобальные распределения мезомасштабных вариаций радиорефракции атмосферы по данным GPS спутника CHAMP // Изв. ВУЗов. Радиофизика. 2016. Т. 59, № 7. C. 593–604., Altieri F., Migliorini A., Zasova L., Shakun A., Piccioni G., Bellucci G. Modeling VIRTIS/VEX O2(a1 delta g) nightglow profiles affected by the propagation of gravity waves in the Venus upper mesosphere. J. Geophys. Res. 2014, vol. 119, pp. 2300–2316. DOI: 10.1002/2013JE004585.
2. Гилл А. Динамика атмосферы и океана. М.: Мир. 1986. Т. 1. 397 с., Cot C., Barat J. Wave-turbulence interaction in the stratosphere: A case study. J. Geophys. Res. 1986, vol. 91, no. D2, pp. 2749–2756.
3. Госсард Э.Э., Хук У.Х. Волны в атмосфере. М.: Мир, 1978. 532 с. р, Creasey J.E., Forbes J.M., Hinson D.P. Global and seasonal distribution of gravity wave activity in Mars’ lower atmosphere derived from MGS radio occultation data. Geophys. Res. Lett. 2006, vol. 33, L01803. DOI: 10.1029/2005GL024037.
4. Губенко В.Н., Павельев А.Г., Салимзянов Р.Р., Андреев В.Е. Методика определения параметров внутренней гравитационной волны по измерению вертикального профиля температуры или плотности в атмосфере Земли // Косм. иссл. 2012. Т. 50, № 1. С. 23–34., Fritts D.C. A review of gravity wave saturation processes, effects, and variability in the middle atmosphere. Pure Appl. Geophys. 1989, vol. 130, pp. 343–371.
5. Губенко В.Н., Кириллович И.А., Павельев А.Г. Характеристики внутренних волн в атмосфере Марса, полученные на основе анализа вертикальных профилей температуры миссии Mars Global Surveyor // Косм. иссл. 2015. Т. 53, № 2. C. 141–151. DOI: 10.7868/S0023420615020028., Fritts D.C., Alexander M.J. Gravity wave dynamics and effects in the middle atmosphere. Rev. Geophys. 2003, vol. 41, no. 1, pp. 1–59. DOI:10.1029/2001RG000106.
Cited by
4 articles.
订阅此论文施引文献
订阅此论文施引文献,注册后可以免费订阅5篇论文的施引文献,订阅后可以查看论文全部施引文献