Mesoscale disturbances in the tropical stratosphere excited by convection: Observations and effects on the stratospheric momentum budget
Journal Article
·
· Journal of the Atmospheric Sciences; (United States)
- NASA/Ames Research Center, Moffett Field, CA (United States)
- San Jose State Univ., CA (United States)
- Synernet, Fremont, CA (United States)
The importance of the momentum flux of topographically generated mesoscale gravity waves to the extratropical middle atmosphere circulation has been well established for over a decade. Estimates of the zonal forcing due to tropical mesoscale gravity waves, however, are hampered by lack of data on their primarily convective sources. The advent of aircraft measurements over tropical convective systems now makes such estimates possible without the use of ad hoc assumptions about amplitudes and phase speeds. Aircraft measurements from NASA's 1980 Panama and 1987 STEP/Australia Missions show that convectively generated disturbances observed just above the tropopause have horizontal scales comparable to those of the underlying anvils (about 50--100 km) with peak-to-peak isentropic surface variations of about 300--400 m. Satellite imagery of tropical anvil evolution indicates a typical lifetime of about five hours. Assuming that each convective system's impact on the stratosphere can be modeled as a time-dependent [open quotes]mountain[close quotes] with the preceding spatial and time scales, the excited spectrum of gravity waves can be calculated. A suitable quasi-linear wave-mean flow interaction parameterization and satellite-derived cloud area statistics can then be used to evaluate the zonal acceleration as a function of altitude induced by gravity waves from mesoscale convective systems. The results indicate maximum westerly accelerations due to breaking mesoscale gravity waves of almost 0.4 m s[sup [minus]1]/day in the upper stratosphere (in the region of the semiannual oscillation) during September, comparable to but probably smaller than the accelerations induced by planetary-scale Kelvin waves. Calculated easterly accelerations due to breaking mesoscale gravity waves in the QBO region below 35 km are smaller, accounting for about 10% of the required zonal acceleration. 35 refs., 14 figs., 1 tab.
- OSTI ID:
- 6531276
- Journal Information:
- Journal of the Atmospheric Sciences; (United States), Journal Name: Journal of the Atmospheric Sciences; (United States) Vol. 50:8; ISSN 0022-4928; ISSN JAHSAK
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
54 ENVIRONMENTAL SCIENCES
540110*
ATMOSPHERIC CIRCULATION
AUSTRALASIA
AUSTRALIA
CENTRAL AMERICA
CONVECTION
DATA ANALYSIS
DEVELOPED COUNTRIES
DEVELOPING COUNTRIES
DISTURBANCES
EARTH ATMOSPHERE
ENERGY TRANSFER
GRAVITY WAVES
HEAT TRANSFER
LATIN AMERICA
MASS TRANSFER
MATHEMATICAL MODELS
MOMENTUM TRANSFER
PANAMA
STRATOSPHERE
TROPICAL REGIONS
TROPOPAUSE
TROPOSPHERE
540110*
ATMOSPHERIC CIRCULATION
AUSTRALASIA
AUSTRALIA
CENTRAL AMERICA
CONVECTION
DATA ANALYSIS
DEVELOPED COUNTRIES
DEVELOPING COUNTRIES
DISTURBANCES
EARTH ATMOSPHERE
ENERGY TRANSFER
GRAVITY WAVES
HEAT TRANSFER
LATIN AMERICA
MASS TRANSFER
MATHEMATICAL MODELS
MOMENTUM TRANSFER
PANAMA
STRATOSPHERE
TROPICAL REGIONS
TROPOPAUSE
TROPOSPHERE