Physics
Scientific paper
Aug 2000
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2000georl..27.2537v&link_type=abstract
Geophysical Research Letters, Volume 27, Issue 16, p. 2537-2540
Physics
4
Meteorology And Atmospheric Dynamics: Remote Sensing, Meteorology And Atmospheric Dynamics: Turbulence, Meteorology And Atmospheric Dynamics: Instruments And Techniques, Radio Science: Radar Atmospheric Physics
Scientific paper
We used the ratio of simultaneous observations of radar reflectivity by S- and UHF-band radars together with Hill's model of refractivity fluctuations due to turbulence to infer ɛ, the rate of viscous dissipation of turbulent kinetic energy per unit mass. Observations were made for 25 days from November 13 to December 7, 1995, at 11.4°S, 130.4°E (about 100 km northwest of Darwin, Australia) during the Maritime Continent Thunderstorm Experiment (MCTEX). The 500 m pulse length data covered the height range 872 to 3032 m MSL. The observed distribution of ɛ has a strong diurnal variation, with mean daytime and night-time values of ɛ of the order of 10-3 and 10-5m2s-3, respectively. With the dual-wavelength technique most non-turbulent echoes (including particulate echoes) are identified and filtered out, since the ensemble of turbulent observations is identified by its conformity to Hill's model. The technique is self-calibrating, requiring only the relative calibration of the two radars using observations during rain, and does not require precise absolute calibration of either radar.
Clark Wallace L.
Ecklund Warner L.
Gage Kenneth S.
VanZandt Thomas E.
Williams Christopher R.
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