2020
DOI: 10.5194/amt-13-5065-2020
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Estimating total attenuation using Rayleigh targets at cloud top: applications in multilayer and mixed-phase clouds observed by ground-based multifrequency radars

Abstract: Abstract. At millimeter wavelengths, attenuation by hydrometeors, such as liquid droplets or large snowflakes, is generally not negligible. When using multifrequency ground-based radar measurements, it is common practice to use the Rayleigh targets at cloud top as a reference in order to derive attenuation-corrected reflectivities and meaningful dual-frequency ratios (DFRs). By capitalizing on this idea, this study describes a new quality-controlled approach that aims at identifying regions of cloud where part… Show more

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Cited by 30 publications
(61 citation statements)
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“…3) The observations presented here reinforce the idea that the sensitivity of all the radar systems involved in future multi-wavelength radar studies should be sufficient to allow the detection of the Rayleigh plateau near the top of ice clouds; that is necessary to ensure that we have a robust estimation of the differential (dual-wavelength) path integrated liquid attenuation (Tridon et al, 2020). For rain studies as well, G-band radar sensitivity should be https://doi.org/10.5194/amt-2020-493 Preprint.…”
supporting
confidence: 65%
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“…3) The observations presented here reinforce the idea that the sensitivity of all the radar systems involved in future multi-wavelength radar studies should be sufficient to allow the detection of the Rayleigh plateau near the top of ice clouds; that is necessary to ensure that we have a robust estimation of the differential (dual-wavelength) path integrated liquid attenuation (Tridon et al, 2020). For rain studies as well, G-band radar sensitivity should be https://doi.org/10.5194/amt-2020-493 Preprint.…”
supporting
confidence: 65%
“…Finally, observations collected above 4.5 km reveal the G-band's strength in small particle regimes. In this region, absence of Ka-W differential signal (i.e., DWR = 0 dB) suggests the presence of Rayleigh targets (Tridon et al, 2020), which for these frequencies correspond to ice populations with PSDs of mass-weighted mean diameter smaller than ~1 mm (Tridon et al, 2019). While Ka-and Wband signals lack sufficient differential scattering to gain further information about such small ice crystals, our 310 observations suggest that G-band signal can; DWR estimated using G-band show differential signals on the order of a few decibels across most the layer (see Fig 5b-c and Fig.…”
Section: Using G-band For Ice Crystals Sizing and Habit Characterizatmentioning
confidence: 99%
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“…Moreover, attenuation by ice particles might be significant if the large amount of ice were produced in the clouds and the radar beam passed through the ice layers. Tridon et al (2020) proposed a relative path-integrated attenuation (PIA) technique to retrieve liquid-water content using DWR profiles. A key idea of this technique is that the DWR 330 from dual frequency radars near cloud tops, where it is expected that small ice crystals are in the Rayleigh scattering regime for both radar wavelengths, is mainly due to the PIA associated with liquid cloud droplets and ice particles.…”
mentioning
confidence: 99%