Numerical Simulations of Two Trapped Mountain Lee Waves Downstream of Oahu

Two trapped lee-wave events dominated by the transverse mode downstream of the island ofOahu in Hawaii—27 January 2010 and 24 January 2003—are simulated using the Weather Research Forecasting (WRF) Model with a horizontal grid size of 1 km in conjunction with the analyses of soundings, weather maps,...

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Bibliographic Details
Published in:Journal of applied meteorology and climatology 2017-05, Vol.56 (5), p.1305-1324
Main Authors: Li, Liye, Chen, Yi-Leng
Format: Article
Language:English
Subjects:
Air parcels
Aircraft
Amplitudes
Atmosphere
Atmospheric pressure
Atmospheric sciences
Aviation
Buoyancy
Climatology
Clouds
Cold
Computer simulation
Convective available potential energy
Dissipation
Earth science
Energy
Flow stability
Froude number
Gravitational waves
Heating
Height
Humidity
Islands
Lee waves
Mathematical models
Mountain waves
Mountains
Numerical simulations
Potential energy
Relative humidity
Satellite imagery
Satellites
Soundings
Tests
Trade winds
Turbulence
Wavelengths
Weather
Weather forecasting
Weather maps
Wind speed
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Summary:Two trapped lee-wave events dominated by the transverse mode downstream of the island ofOahu in Hawaii—27 January 2010 and 24 January 2003—are simulated using the Weather Research Forecasting (WRF) Model with a horizontal grid size of 1 km in conjunction with the analyses of soundings, weather maps, and satellite images. The common factors for the occurrences of these transverse trapped mountain-wave events are 1) Froude number [Fr =U/(Nh)>1, where U is the upstream speed of the cross-barrier flow, N is stability, and h is the mountain height; 2) insufficient convective available potential energy for the air parcel to become positively buoyant after being lifted to the top of the stable trade wind inversion layer; and 3) increasing cross-barrier wind speed with respect to height through the stable inversion layer, satisfying Scorer’s criteria between the inversion layer and the layer aloft. Within the inversion layer, where the Scorer parameter has a maximum, the wave amplitudes are the greatest. The two trapped mountain waves in winter occurred under strong prefrontal stably stratified southwesterly flow. On the other islands in Hawaii, where the mountaintops are below the base of the inversion, transverse trapped lee waves can occur under similar large-scale settings if the mountain height is lower than U/N. The high-spatial-and-temporal-resolution WRF Model successfully simulates the onset, development, and dissipation of these two events. Sensitivity tests for the 27 January 2010 case are performed with reduced relative humidity (RH). With a lower RH and less-significant latent heating, trapped lee waves have smaller amplitudes and shorter wavelengths.
ISSN:1558-8424
1558-8432
DOI:10.1175/JAMC-D-15-0341.1