Editorial Type:
Article
Article Type:
Research Article

Intensive Probing of a Clear Air Convective Field by Radar and Instrumented Drone Aircraft

J. R. Rowland Applied Physics Laboratory, The Johns Hopkins University, Silver Spring, Md. 20910

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Print Publication:
01 Feb 1973
DOI:
https://doi.org/10.1175/1520-0450(1973)012<0149:IPOACA>2.0.CO;2
Page(s):
149–155
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Abstract

An instrumented drone aircraft was used in conjunction with ultrasensitive radar to study the development of a convective field in the clear air. Radar data are presented which show an initial constant growth rate in the height of the convective field of 3.8 m min−1, followed by a short period marked by condensation and rapid growth at a rate in excess of 6.1 m min−1.

Drone aircraft soundings show general features of a convective field including progressive lifting of the inversion at the top of the convection and a cooling of the air at the top of the field. Calculations of vertical heat flux as a function of time and altitude during the early stages of convection show a linear decrease in heat flux with altitude to near the top of the convective field and a negative heat flux at the top.

Evidence is presented which supports previous observations that convective cells overshoot their neutral buoyancy level into a region where they are cool and moist compared to their surroundings. Furthermore, only that portion of the convective cell that has overshot its neutral buoyancy level is generally visible to the radar.

Abstract

An instrumented drone aircraft was used in conjunction with ultrasensitive radar to study the development of a convective field in the clear air. Radar data are presented which show an initial constant growth rate in the height of the convective field of 3.8 m min−1, followed by a short period marked by condensation and rapid growth at a rate in excess of 6.1 m min−1.

Drone aircraft soundings show general features of a convective field including progressive lifting of the inversion at the top of the convection and a cooling of the air at the top of the field. Calculations of vertical heat flux as a function of time and altitude during the early stages of convection show a linear decrease in heat flux with altitude to near the top of the convective field and a negative heat flux at the top.

Evidence is presented which supports previous observations that convective cells overshoot their neutral buoyancy level into a region where they are cool and moist compared to their surroundings. Furthermore, only that portion of the convective cell that has overshot its neutral buoyancy level is generally visible to the radar.

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Cover Journal of Applied Meteorology and Climatology
Journal of Applied Meteorology and Climatology