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DOI | 10.1016/j.atmosres.2019.104836 |
Relationship between airborne electrical and total water content measurements in ice clouds | |
Bouchard A.; Lalande P.; Laroche P.; Blanchet P.; Buguet M.; Chazottes A.; Walter Strapp J. | |
发表日期 | 2020 |
ISSN | 0169-8095 |
卷号 | 237 |
英文摘要 | During the High Altitude Ice Crystal -High Ice Water Content (HAIC-HIWC) project, instrumented aircraft were flown in the vicinity and inside deep tropical convective clouds. Among the probes installed on one of these aircraft, were the Isokinetic Probe (IKP2), to retrieve the cloud total water content (TWC) and the AMPERA (Atmospheric Measurement of Potential and Electric field on Aircraft) system to provide information on the electrostatic state of the atmosphere and the aircraft. AMPERA is an electric field mill network which locally measures the electrostatic field at the aircraft fuselage. The distribution and amplitude of the electrostatic field on the aircraft skin depends on the atmospheric electrostatic field around the aircraft and the net electric charge of the aircraft. This latter parameter depends on the balance between the triboelectric current due to the impact of the cloud particles on the aircraft fuselage, the current due to the charged particles emitted by the engines, and the corona current emitted by the aircraft. Based on the flights of the HAIC-HIWC campaigns, which were conducted almost exclusively in cloud composed of ice particles, a comparison between the total water content recorded by microphysical sensor and the aircraft net charge has highlighted the possibility of deducing an estimate of the TWC from the aircraft electrical potential. In contrast to conventional TWC probes which sample a local area of the atmosphere, the AMPERA system uses the aircraft as a sensor and provides an overall estimation of its net TWC exposure. This study provides the first results of the efficacy of the electrostatic method through comparisons with direct in-situ bulk TWC measurements in ice clouds. © 2020 Elsevier B.V. |
学科领域 | Aircraft; Charged particles; Clouds; Electric discharges; Ice; Probes; Atmospheric measurement; Convective clouds; Electric field mill; Electrical potential; Electrostatic state; Ice water content; Overall estimation; Total water content; Fuselages; airborne survey; aircraft; cloud water; comparative study; convective cloud; electric field; ice; measurement method |
语种 | 英语 |
scopus关键词 | Aircraft; Charged particles; Clouds; Electric discharges; Ice; Probes; Atmospheric measurement; Convective clouds; Electric field mill; Electrical potential; Electrostatic state; Ice water content; Overall estimation; Total water content; Fuselages; airborne survey; aircraft; cloud water; comparative study; convective cloud; electric field; ice; measurement method |
来源期刊 | Atmospheric Research
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文献类型 | 期刊论文 |
条目标识符 | http://gcip.llas.ac.cn/handle/2XKMVOVA/120452 |
作者单位 | DPHY, ONERA, Université Paris Saclay, Châtillon, F-92322, France; Met Analytics Inc., Canada |
推荐引用方式 GB/T 7714 | Bouchard A.,Lalande P.,Laroche P.,et al. Relationship between airborne electrical and total water content measurements in ice clouds[J],2020,237. |
APA | Bouchard A..,Lalande P..,Laroche P..,Blanchet P..,Buguet M..,...&Walter Strapp J..(2020).Relationship between airborne electrical and total water content measurements in ice clouds.Atmospheric Research,237. |
MLA | Bouchard A.,et al."Relationship between airborne electrical and total water content measurements in ice clouds".Atmospheric Research 237(2020). |
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