The use of dual channel circular-polarization radar observations for remotely sensing storm electrification

Abstract

Observations of thunderstorms with a dual channel circularpolarization radar have provided dramatic indications of the buildup of the electric field inside the storms and of the sudden collapse of the field at the time of lightning. The indications are obtained by coherently correlating the simultaneous returns in the right- and left-hand circular polarization channels of the radar, and follow up on the pioneering observations of this type by Hendry and McCormick (1976). The correlation is estimated and displayed in real time and the results enable one to predict when a storm has the potential for producing a lightning discharge, and often to anticipate the occurrence of individual discharges. The observations detect the presence of electrically aligned particles, believed to be small ice crystals, which are aligned by the electrostatic field of the storm. The aligned particles cause the radar signal to become progressively depolarized as it propagates through an alignment region, giving rise to correlated right- and left-circular polarization echoes. The alignment direction can be determined from the phase of the correlation and is found to be predominantly vertical, indicating a similar electric field orientation. Weaker horizontal alignment is often observed immediately following lightning discharges, consistent with the idea that the aligned particles are ice platelets which fall with horizontal orientation due to aerodynamic forces. The observations have been found to reveal the onset of strong electrification in developing storms and to indicate when decaying storms no longer have the potential to produce lightning. By compensating for signal-to-noise effects, the variation of the depolarization with range can be determined. This provides detailed pictures of the alignment regions which could be used as tracers of ice crystal populations in storms. The pictures also show the spatial variation of the alignment directions, raising the possibility of remotely mapping the storm electric field structure. Finally, the depolarization rate results readily enable one to distinguish between liquid and solid precipitation in the storms.