An airborne profiling radar study of the impact of glaciogenic cloud seeding on snowfall from winter orographic clouds

Bart Geerts; Qun Miao; Yang Yang; Roy Rasmussen; Daniel Breed

doi:10.1175/2010JAS3496.1

An airborne profiling radar study of the impact of glaciogenic cloud seeding on snowfall from winter orographic clouds

Bart Geerts, Qun Miao, Yang Yang, Roy Rasmussen, Daniel Breed

Research output: Contribution to journal › Article › peer-review

58 Scopus citations

Abstract

Data from an airborne vertically pointing millimeter-wave Doppler radar are used to study the cloud microphysical effect of glaciogenic seeding of cold-season orographic clouds. Fixed flight tracks were flown downstream of ground-based silver iodide (AgI) generators in the Medicine Bow Mountains of Wyoming. Composite data from seven flights, each with a no-seeding period followed by a seeding period, indicate that radar reflectivity was higher near the ground during the seeding periods. Several physical considerations argue in favor of the hypothesis that the increase in near-surface reflectivity is attributed to AgI seeding. While the increase in near-surface reflectivity and thus snowfall rate are statistically significant, caution is warranted in view of the large natural variability of weather conditions and the small size of the dataset.

Original language	English
Pages (from-to)	3286-3302
Number of pages	17
Journal	Journal of the Atmospheric Sciences
Volume	67
Issue number	10
DOIs	https://doi.org/10.1175/2010JAS3496.1
State	Published - Oct 2010
Externally published	Yes

Keywords

Aircraft observations
Cloud microphysics
Cloud seeding
Orographic effects
Radars/radar observations
Weather modification
Winter/cool season

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10.1175/2010JAS3496.1

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title = "An airborne profiling radar study of the impact of glaciogenic cloud seeding on snowfall from winter orographic clouds",

abstract = "Data from an airborne vertically pointing millimeter-wave Doppler radar are used to study the cloud microphysical effect of glaciogenic seeding of cold-season orographic clouds. Fixed flight tracks were flown downstream of ground-based silver iodide (AgI) generators in the Medicine Bow Mountains of Wyoming. Composite data from seven flights, each with a no-seeding period followed by a seeding period, indicate that radar reflectivity was higher near the ground during the seeding periods. Several physical considerations argue in favor of the hypothesis that the increase in near-surface reflectivity is attributed to AgI seeding. While the increase in near-surface reflectivity and thus snowfall rate are statistically significant, caution is warranted in view of the large natural variability of weather conditions and the small size of the dataset.",

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doi = "10.1175/2010JAS3496.1",

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T1 - An airborne profiling radar study of the impact of glaciogenic cloud seeding on snowfall from winter orographic clouds

AU - Geerts, Bart

AU - Miao, Qun

AU - Yang, Yang

AU - Rasmussen, Roy

AU - Breed, Daniel

PY - 2010/10

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N2 - Data from an airborne vertically pointing millimeter-wave Doppler radar are used to study the cloud microphysical effect of glaciogenic seeding of cold-season orographic clouds. Fixed flight tracks were flown downstream of ground-based silver iodide (AgI) generators in the Medicine Bow Mountains of Wyoming. Composite data from seven flights, each with a no-seeding period followed by a seeding period, indicate that radar reflectivity was higher near the ground during the seeding periods. Several physical considerations argue in favor of the hypothesis that the increase in near-surface reflectivity is attributed to AgI seeding. While the increase in near-surface reflectivity and thus snowfall rate are statistically significant, caution is warranted in view of the large natural variability of weather conditions and the small size of the dataset.

AB - Data from an airborne vertically pointing millimeter-wave Doppler radar are used to study the cloud microphysical effect of glaciogenic seeding of cold-season orographic clouds. Fixed flight tracks were flown downstream of ground-based silver iodide (AgI) generators in the Medicine Bow Mountains of Wyoming. Composite data from seven flights, each with a no-seeding period followed by a seeding period, indicate that radar reflectivity was higher near the ground during the seeding periods. Several physical considerations argue in favor of the hypothesis that the increase in near-surface reflectivity is attributed to AgI seeding. While the increase in near-surface reflectivity and thus snowfall rate are statistically significant, caution is warranted in view of the large natural variability of weather conditions and the small size of the dataset.

KW - Aircraft observations

KW - Cloud microphysics

KW - Cloud seeding

KW - Orographic effects

KW - Radars/radar observations

KW - Weather modification

KW - Winter/cool season

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DO - 10.1175/2010JAS3496.1

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An airborne profiling radar study of the impact of glaciogenic cloud seeding on snowfall from winter orographic clouds

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Keywords

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