High-Resolution Vertical Profiles of X-Band Polarimetric Radar Observables during Snowfall in the Swiss Alps

Schneebeli, M.; Dawes, Nicholas; Lehning, Michael; Berne, Alexis

doi:10.1175/jamc-d-12-015.1

Cited by 97 publications

(85 citation statements)

References 42 publications

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“…Similar trends were observed when a different hydrometeor classification method was employed (i.e., the method of Dolan and Rutledge, 2009, not shown here). The relation between riming and snowfall intensity was also qualitatively observed by Schneebeli et al (2013) in a different location in the Swiss Alps. It must be noted that these results rely on radar-based hydrometeor classification (i.e., indirect measurements), and also that riming does not exclude the occurrence of other microphysical processes, notably aggregation.…”

Section: Riming and Snowfall Accumulationmentioning

confidence: 52%

“…The peak of K dp , below altitudes of higher Z DR and above altitudes of higher Z H , is a well-known but still not completely understood signature observed during snowfall (Kennedy and Rutledge, 2011;Bechini et al, 2013;Schneebeli et al, 2013;Andric et al, 2013;Hubbert et al, 2014). The proximity of this signature with respect to the −15 • C level (blue line in Fig.…”

Section: Intermediate Level Of Precipitationmentioning

confidence: 82%

“…The system, named MXPol, is an X-band (3.2 cm wavelength) radar with angular resolution of about 1.5 • and range resolution of 75 m (complete specifications are given in Schneebeli et al, 2013;Scipion et al, 2013). MXPol provides as main products the reflectivity factor at horizontal polarization Z H (dBZ), differential reflectivity Z DR (dB), copolar cross-correlation coefficient ρ hv , specific differential phase shift upon propagation K dp ( • km −1 ), mean Doppler velocity v (m s −1 ) and Doppler spectrum width σ v (Doviak and Zrnić, 2006).…”

Section: Kleine Scheidegg (Ks)mentioning

confidence: 99%

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Polarimetric radar and in situ observations of riming and snowfall microphysics during CLACE 2014

et al. 2015

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Abstract. This study investigates the microphysics of winter alpine snowfall occurring in mixed-phase clouds in an inner-Alpine valley during January and February 2014. The available observations include high-resolution polarimetric radar and in situ measurements of the ice-phase and liquidphase components of clouds and precipitation. Radar-based hydrometeor classification suggests that riming is an important factor to favor an efficient growth of the precipitating mass and correlates with snow accumulation rates at ground level. The time steps during which rimed precipitation is dominant are analyzed in terms of temporal evolution and vertical structure. Snowfall identified as rimed often appears after a short time period during which the atmospheric conditions favor wind gusts and updrafts and supercooled liquid water (SLW) is available. When a turbulent atmospheric layer persists for several hours and ensures continuous SLW generation, riming can be sustained longer and large accumulations of snow at ground level can be generated. The microphysical interpretation and the meteorological situation associated with one such event are detailed in the paper. The vertical structure of polarimetric radar observations during intense snowfall classified as rimed shows a peculiar maximum of specific differential phase shift K dp , associated with large number concentrations and riming of anisotropic crystals. Below this K dp peak there is usually an enhancement in radar reflectivity Z H , proportional to the K dp enhancement and interpreted as aggregation of ice crystals. These signatures seem to be recurring during intense snowfall.

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Section: Riming and Snowfall Accumulationmentioning

confidence: 52%

Section: Intermediate Level Of Precipitationmentioning

confidence: 82%

Section: Kleine Scheidegg (Ks)mentioning

confidence: 99%

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Polarimetric radar and in situ observations of riming and snowfall microphysics during CLACE 2014

et al. 2015

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“…This system, described in Schneebeli et al (2013) and in Scipion et al (2013), is a scanning dual-polarization Doppler radar. During its operation period at DDU, it was mainly collecting data at 75 m radial resolution and a maximum radial distance of 30 km, mostly conducting different types of scans within a repeating scanning sequence of 5 min: (i) plan position indicator (PPI) scans, i.e., quasi-horizontal slices of the atmosphere, (ii) range height indicator (RHI) scans, i.e., vertical slices of the atmosphere, and (iii) static vertical profiles, such as the ones performed by the MRR.…”

Section: Apres3 Instrumentsmentioning

confidence: 99%

Measurements of precipitation in Dumont d'Urville, Adélie Land, East Antarctica

et al. 2017

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“…Also used were data from a METEK GmbH micro rain radar (MRR Peters et al, 2002Tridon et al, 2011) within the network, which provided vertical profiles of estimated DSDs recorded with 100 m vertical resolution and 10 s integration time. MXPol, a transportable Doppler dual-polarisation weather radar (for instrument details see Schneebeli et al, 2013), was located to the north-east of the disdrometer network. In 2013, MXPol recorded "stacked" plan position indicator (PPI) scans above the Parsivel network at elevations of 4, 5, 6, 8, 10, 12, 14, 16, and 20 • above horizontal, with a return time of about 6 min.…”

Section: Double-moment Dsd Normalisationmentioning

confidence: 99%

Retrieval of the raindrop size distribution from polarimetric radar data using double-moment normalisation

Raupach¹,

Berne²

2017

Atmos. Meas. Tech.

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Abstract.A new technique for estimating the raindrop size distribution (DSD) from polarimetric radar data is proposed. Two statistical moments of the DSD are estimated from polarimetric variables, and the DSD is reconstructed using a double-moment normalisation. The technique takes advantage of the relative invariance of the double-moment normalised DSD. The method was tested using X-band radar data and networks of disdrometers in three different climatic regions. Radar-derived estimates of the DSD compare reasonably well to observations. In the three tested domains, in terms of DSD moments, rain rate, and characteristic drop diameter, the proposed method performs similarly to and often better than a state-of-the-art DSD-retrieval technique. The approach is flexible because no specific DSD model is prescribed. In addition, a method is proposed to treat noisy radar data to improve DSD-retrieval performance with radar measurements.

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High-Resolution Vertical Profiles of X-Band Polarimetric Radar Observables during Snowfall in the Swiss Alps

Cited by 97 publications

References 42 publications

Polarimetric radar and in situ observations of riming and snowfall microphysics during CLACE 2014

Polarimetric radar and in situ observations of riming and snowfall microphysics during CLACE 2014

Measurements of precipitation in Dumont d'Urville, Adélie Land, East Antarctica

Retrieval of the raindrop size distribution from polarimetric radar data using double-moment normalisation

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