Charge transfer measurements during single ice crystal collisions with a target growing by riming

R.G. PEREYRA; E.E. AVILA

JOURNAL OF GEOPHYSICAL RESEARCH

AMERICAN GEOPHYSICAL UNION

Año: 2002 vol. 107 p. 1 - 9

0148-0227

Direct measurements of the electric charge separated from individual collisions between vapor grown ice crystals and an artificial graupel growing by riming have been made in the present laboratory work. The measurements were performed with an impact velocity of 8.5 m s
1, the ambient temperature was varied in the range
5 to
1, the ambient temperature was varied in the range
5 to
20
C, the average ice crystal sizes between 20 to 40 mm, with an effective liquid water content up to 1.5 g m
3. The magnitude of the charge separated per collision is on the order of 10 fC, and the sign of the average charge depends on the ambient temperature for the present EW. We found that the artificial graupel charges positively for temperatures above
12
C and negatively for temperatures below
14
C. The current results are compared with those obtained by other authors that used the multiple crystal collision technique.20
C, the average ice crystal sizes between 20 to 40 mm, with an effective liquid water content up to 1.5 g m
3. The magnitude of the charge separated per collision is on the order of 10 fC, and the sign of the average charge depends on the ambient temperature for the present EW. We found that the artificial graupel charges positively for temperatures above
12
C and negatively for temperatures below
14
C. The current results are compared with those obtained by other authors that used the multiple crystal collision technique.
3. The magnitude of the charge separated per collision is on the order of 10 fC, and the sign of the average charge depends on the ambient temperature for the present EW. We found that the artificial graupel charges positively for temperatures above
12
C and negatively for temperatures below
14
C. The current results are compared with those obtained by other authors that used the multiple crystal collision technique.
12
C and negatively for temperatures below
14
C. The current results are compared with those obtained by other authors that used the multiple crystal collision technique.