Simulation of microwave emission from physically modeled snowpacks

Abstract Detailed knowledge of snowpack properties is crucial for the interpretation and modeling of thermal microwave radiation. Here we use two well-known snow models, Crocus and SNTHERM, to obtain snow profiles from meteorological data. These profiles are compared with pit profiles and used as input to the Microwave Emission Model of Layered Snowpacks (MEMLS) for the simulation of microwave radiation. The snow-profile data can be applied almost directly. Adaptation is needed only in the conversion of the grain-size used in the snow models to the correlation length used in the emission model; it is based on empirical fits. The resulting emissivities are compared with in situ microwave measurements. The computed snow depths are in good agreement with observations. Comparison of selected profiles shows that Crocus is in good agreement with the pit profile, but the density of simulated melt-freeze crusts is underestimated. The SNTHERM profiles show no such crusts, and the density deviates from the pit profiles. The computed temporal behavior of the snowpack emissivity is reasonable. Comparison of selected situations with in situ measurements indicates good agreement. However, the polarization difference tends to be underestimated because of inaccuracies in the simulation of density profiles. The results show the potential of combined snow-physical and microwave-emission models for understanding snow signatures and for developing snow algorithms for microwave remote sensing. Based on the frequency-selective penetration and on the high sensitivity to snow texture, density and wetness, microwave radiometry can offer a new dimension to snow physics. Potential applications are described.

[1]  Jin Au Kong,et al.  Modeling of Millimeter Wave Backscatter of Time-Varying Snowcover — Summary , 1997 .

[2]  A. England,et al.  Seasonal snowpack radiobrightness interpretation using a SVAT‐linked emission model , 1997 .

[3]  E. Martin,et al.  A meteorological estimation of relevant parameters for snow models , 1993 .

[4]  C. Matzler,et al.  Radiometric and structural measurements of snow samples , 1995, 1995 International Geoscience and Remote Sensing Symposium, IGARSS '95. Quantitative Remote Sensing for Science and Applications.

[5]  Christian Mätzler,et al.  Applications of the interaction of microwaves with the natural snow cover , 1987 .

[6]  Christian Mätzler,et al.  Autocorrelation functions of granular media with free arrangement of spheres, spherical shells or ellipsoids , 1997 .

[7]  E. Brun,et al.  A numerical model to simulate snow-cover stratigraphy for operational avalanche forecasting , 1992, Journal of Glaciology.

[8]  E. Brun,et al.  An efficient method for a delayed and accurate characterization of snow grains from natural snowpacks , 1991 .

[9]  Jin Au Kong,et al.  Modeling of Millimeter Wave Backscatter of Time-Varying Snowcover , 1997 .

[10]  E. Svendsen,et al.  A model for retrieving total sea ice concentration from a spaceborne dual-polarized passive microwave instrument operating near 90 GHz , 1987 .

[11]  E. Martin,et al.  An Energy and Mass Model of Snow Cover Suitable for Operational Avalanche Forecasting , 1989, Journal of Glaciology.

[12]  R. Jordan A One-dimensional temperature model for a snow cover : technical documentation for SNTHERM.89 , 1991 .

[13]  Andreas Wiesmann,et al.  Extension of the Microwave Emission Model of Layered Snowpacks to Coarse-Grained Snow , 1999 .

[14]  A. Wiesmann,et al.  Microwave Emission Model of Layered Snowpacks , 1999 .

[15]  Schnee und Landschaft Eidgenössische Forschungsanstalt fü Wald Schnee und Lawinen in den Schweizer Alpen , 1936 .

[16]  C. Fierz Field observation and modelling of weak-layer evolution , 1998, Annals of Glaciology.

[17]  Christian Mätzler,et al.  Passive microwave signatures of landscapes in winter , 1994 .