Abstract
Vertical turbulent transports of latent and sensible heat through the tropical marine boundary layer were measured with ship and airborne instruments in the GATE experimental area. The measurements from the two systems are compared for cases of simultaneous sampling in the same locations during undisturbed weather and during the wakes of convective disturbances. The paired average fluxes from the airborne eddy correlation measurements and the shipboard bulk aerodynamic measurements, for undisturbed weather, are related with correlation coefficients in the range of 0.6 to 0.9; the correlations depend primarily on stratifications of the aircraft data according to sampling altitude (15–153 m msl) and flight pattern relative to the mean wind. The agreement between the two types of measurements is best for ship data paired with aircraft samples from the lowest altitudes (15 and 30 m) and from alongwind rather than crosswind flights, as is appropriate since the stationary ships monitor the alongwind characteristics of the turbulence. The use of long (1–3 hr) versus short (10 min) ship samples did not significantly affect the comparability with the aircraft samples during undisturbed periods.
The good baseline comparability demonstrated by the undisturbed-weather comparisons was applied to interpret the results from the wakes behind showers. Although these paired measurements were few, not only the sensible heat, but also the latent heat flux was shown to decrease substantially with altitude from 10 m to at least 150 m in the wakes, where the mixing was relatively intense. Variations in the fluxes were much greater at the higher level than nearer the sea surface.
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Barnes, G., Emmitt, G. D., Brümmer, B., LeMone, M. A., and Nicholls, S.: 1980, ‘The Structure of a Fair Weather Boundary Layer Based on the Results of Several Measurement Strategies’, Mon. Wea. Rev. 108, 349–364.
Barnes, G.: 1980, ‘Subcloud Layer Energetics of Precipitating Convection’, Ph.D. Thesis, University of Virginia, Charlottesville. 212 pp.
Bean, B. R.: 1979, ‘Comment on “Evaluation of Evaporation from Lake Ontario During IFYGL by a Modified Mass Transfer Equation” by David W. Phillips’, Water Resources Res. 15, 731.
Bean, B. R., Emmanuel, C. B., Gilmer, R. O., and McGavin, R. E.: 1975, ‘Spatial and Temporal Variations of the Turbulent Fluxes of Heat, Momentum and Water Vapor over Lake Ontario During IFGYL’, NOAA Tech. Rpt. ERL 313-WMPO 5. U.S. Government Printing Office, Wash., D.C., 57 pp.
Bean, B. R., Gilmer, R., Grossman, R. L., McGavin, R., and Travis, C.: 1972, ‘An Analysis of Airborne Measurements of Vertical Water Vapor Flux During BOMEX’, J. Atmos. Sci. 29, 860–869.
Bean, B. R., Gilmer, R. O., Harmann, R. F., McGavin, R. E., and Reinking, R. F.: 1976, ‘Airborne Measurement of Vertical Boundary Layer Fluxes of Water Vapor, Sensible Heat and Momentum During GATE’, NOAA Tech. Memo. ERL WMPO-36 (U.S. Government Printing Office: 1977-779-072 Region No. 8), 83 pp.
Brook, R. R.: 1979, ‘The Influence of Water Vapour Fluctuations on Turbulent Fluxes’, Boundary-Layer Meteorol. 15, 481–487.
Godshall, F. A., Seguin, W. R., and Sabol, P.: 1976, ‘GATE Convection Subprogram Data Center: Analysis of Ship Surface Meteorologucal Data obtained during GATE Intercomparison Periods’, NOAA Tech. Rpt. EDS 17, NTIS, Washington, D.C. 73 pp.
Panofsky, H. and Brier, G.: 1968, Some Applications of Statistics to Meteorology. The Pennsylvania State University Press, 224 pp.
Reinking, R. F.: 1977, ‘The Statistical Nature of Vertical Eddy Motion During GATE’. Preprints, 11th Tech. Conf. Hurricanes and Tropical Meteorology, Miami Beach. Amer. Meteorol. Soc., Boston, pp. 232–237.
Reinking, R. F.: 1980a, ‘Vertical Eddy Motion and Energy Transfer at Very Low Altitudes over the Tropical Atlantic Ocean’, GATE Supplement I, Deep-Sea Res. 26, 23–49.
Reinking, R. F.: 1980b, ‘The Respective Effects of Water Vapor and Temperature on Turbulent Fluxes of Sensible and Latent Heat’, Boundary-Layer Meteorol. 19, 373–385.
Seguin, W. R., Sabol, P., Crayton, R., Crown, R. S., Echternacht, K. L. and Poindexter, M.: 1977, ‘U.S. National Processing Center for GATE: B-Scale Surface Meteorological and Radiation System, Including Instrumentation, Processing and Archived Data’, NOAA Tech. Rpt. EDS 22, U.S. Government Printing Office, Washington, D.C.
Seguin, W. R., Crayton, R., Sabol, P., and Carlile, J. W.: 1978, ‘GATE Convective Subprogram Data Center: Final Report on Ship Surface Data Validation’, NOAA Tech. Rpt. EDS 25, NTIS Washington, D.C. 78 pp.
U.S. GATE Central Program Workshop, 1977: Report available from the National Center for Atmospheric Research, Boulder, Colorado. 723 pp.
Zipser, E. J.: 1977, ‘Mesoscale and Convective-Scale Downdrafts as Distinct Components of Squall-Line Structure’, Mon. Wea. Rev., 105, 1568–1589.
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Reinking, R.F., Barnes, G. A comparison of tropical oceanic heat fluxes determined by airborne eddy correlation and shipboard bulk aerodynamic techniques. Boundary-Layer Meteorol 20, 353–370 (1981). https://doi.org/10.1007/BF00121379
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DOI: https://doi.org/10.1007/BF00121379