Abstract
Remote-sensing observations are needed to estimate the regional and global impacts of snow. However, to retrieve accurate estimates of snow mass and rate, these observations require augmentation through additional information and assumptions about hydrometeor properties. The Precipitation Imaging Package (PIP) provides information about precipitation characteristics and can be utilized to improve estimates of snowfall rate and accumulation. Here, the goal is to demonstrate the quality and utility of two higher-order PIP-derived products: liquid water equivalent snow rate and an approximation of volume-weighted density called equivalent density. Accuracy of the PIP snow rate and equivalent density is obtained through intercomparison with established retrieval methods and through evaluation with colocated ground-based observations. The results confirm the ability of the PIP-derived products to quantify properties of snow rate and equivalent density, and demonstrate that the PIP produces physically realistic snow characteristics. When compared to the National Weather Service (NWS) snow field measurements of six-hourly accumulation, the PIP-derived accumulations were biased only +2.48% higher. Additionally, this work illustrates fundamentally different microphysical and bulk features of low and high snow-to-liquid ratio events, through assessment of observed particle size distributions, retrieved mass coefficients, and bulk properties. Importantly, this research establishes the role that PIP observations and higher-order products can serve for constraining microphysical assumptions in ground-based and spaceborne remotely sensed snowfall retrievals.
Highlights
Remote-sensing observations, principally radar, and passive microwave measurements, provide essential information for estimating and forecasting the impacts of precipitation, and relevantAtmosphere 2020, 11, 785; doi:10.3390/atmos11080785 www.mdpi.com/journal/atmosphereAtmosphere 2020, 11, 785 observing platforms provide coverage both nationally and globally [1,2,3]
Both of these low snow-to-liquid ratio (SLR) Lake-effect Snow (LeS) events have extremely cold temperatures, which likely indicates that boundary layer temperatures were colder than the dendritic growth zone (DGZ) and would not be an environment conducive to large particle growth [52]
The results detailed in this work confirm the ability of the Precipitation Imaging Package (PIP)-derived products to quantify properties of liquid water equivalent (LWE) snow rate, ρe, and SLR
Summary
Atmosphere 2020, 11, 785 observing platforms provide coverage both nationally and globally [1,2,3]. These observations contain incomplete information about the precipitation, assumptions about hydrometeor properties are required in order to retrieve accurate estimates of mass and rate. This is especially true for snow, as more complicated physical properties drive estimation uncertainties [4,5,6].
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