Detection of tropical deep convective clouds from AMSU‐B water vapor channels measurements

Abstract. To simulate passive microwave radiances in allsky conditions requires better knowledge of the scattering properties of frozen hydrometeors. Typically, snow particles are represented as spheres and their scattering properties are calculated using Mie theory, but this is unrealistic and, particularly in deep-convective areas, it produces too much scattering in mid-frequencies (e.g. 30-50 GHz) and too little scattering at high frequencies (e.g. 150-183 GHz). These problems make it hard to assimilate microwave observations in numerical weather prediction (NWP) models, particularly in situations where scattering effects are most important, such as over land surfaces or in moisture sounding channels. Using the discrete dipole approximation to compute scattering properties, more accurate results can be generated by modelling frozen particles as ice rosettes or simplified snowflakes, though hexagonal plates and columns often give worse results than Mie spheres. To objectively decide on the best particle shape (and size distribution) this study uses global forecast departures from an NWP system (e.g. observation minus forecast differences) to indicate the quality of agreement between model and observations. It is easy to improve results in one situation but worsen them in others, so a rigorous method is needed: four different statistics are checked; these statistics are required to stay the same or improve in all channels between 10 GHz and 183 GHz and in all weather situations globally. The optimal choice of snow particle shape and size distribution is better across all frequencies and all weather conditions, giving confidence in its physical realism. Compared to the Mie sphere, most of the systematic error is removed and departure statistics are improved by 10 to 60 %. However, this improvement is achieved with a simple "one-size-fits-all" shape for snow; there is little additional benefit in choosing the particle shape according to the precipitation type. These developments have improved the accuracy of scattering radiative transfer sufficiently that microwave all-sky assimilation is being extended to land surfaces, to higher frequencies and to sounding channels.

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“…Buehler and John, 2005) and to deep convection (e.g. Hong et al, 2005). It should not be affected by issues with the land surface emissivity.…”

Section: Results Over Landmentioning

confidence: 99%

“…By contrast, at 150 GHz, where scattering from upper-level ice and snow is expected to depress TBs (e.g. Hong et al, 2005), the Mie simulations do not provide enough scattering. The DDA simulations are based on the Liu (2008) sector snowflake, a shape that will later be identified as optimal by this study.…”

Section: Introductionmentioning

confidence: 99%

Improved scattering radiative transfer for frozen hydrometeors at microwave frequencies

2014

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“…The use of microwave radiometry for water vapor profiling allows retrieval in cloud-covered scenes, within limits determined by the extent of scattering by large hydrometeors (Greenwald and Christopher 2002;Hong et al 2005). The six channels all measure the same water vapor absorption line but with different radiometric sensitivity.…”

Section: Saphir and Megha-tropiquesmentioning

confidence: 99%

Structure and Dynamical Influence of Water Vapor in the Lower Tropical Troposphere

et al. 2017

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In situ, airborne and satellite measurements are used to characterize the structure of water vapor in the lower tropical troposphere-below the height, z Ã ; of the triple-point isotherm, T Ã : The measurements are evaluated in light of understanding of how lowertropospheric water vapor influences clouds, convection and circulation, through both radiative and thermodynamic effects. Lower-tropospheric water vapor, which concentrates in the first few kilometers above the boundary layer, controls the radiative cooling profile of the boundary layer and lower troposphere. Elevated moist layers originating from a preferred level of convective detrainment induce a profile of radiative cooling that drives circulations which reinforce such features. A theory for this preferred level of cumulus termination is advanced, whereby the difference between T Ã and the temperature at which primary ice forms gives a 'first-mover advantage' to glaciating cumulus convection, thereby concentrating the regions of the deepest convection and leading to more clouds and moisture near the triple point. A preferred level of convective detrainment near T Ã implies relative humidity reversals below zÃ which are difficult to identify using retrievals from satellite-borne microwave and infrared sounders. Isotopologues retrievals provide a hint of such features and their ability to constrain the structure of the vertical humidity profile merits further study. Nonetheless, it will likely remain challenging to resolve dynamically -017-9420-8 important aspects of the vertical structure of water vapor from space using only passive sensors.

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“…The currently operational microwave sensors are sensitive only to relatively thick ice clouds (e.g. Hong et al, 2005), because the interaction of millimetre-wave radiation with cloud ice particles is not very strong. For submillimetrewave radiation, the interaction is significantly stronger.…”

mentioning

confidence: 99%

A concept for a satellite mission to measure cloud ice water path, ice particle size, and cloud altitude

Buehler

Jiménez

Evans

et al. 2007

Q.J.R. Meteorol. Soc.

124

120

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ABSTRACT:A passive satellite radiometer operating at submillimetre wavelengths can measure cloud ice water path (IWP), ice particle size, and cloud altitude. The paper first discusses the scientific background for such measurements. Formal scientific mission requirements are derived, based on this background and earlier assessments. The paper then presents a comprehensive prototype instrument and mission concept, and demonstrates that it meets the requirements.

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Detection of tropical deep convective clouds from AMSU‐B water vapor channels measurements

Cited by 166 publications

References 65 publications

Improved scattering radiative transfer for frozen hydrometeors at microwave frequencies

Improved scattering radiative transfer for frozen hydrometeors at microwave frequencies

Structure and Dynamical Influence of Water Vapor in the Lower Tropical Troposphere

A concept for a satellite mission to measure cloud ice water path, ice particle size, and cloud altitude

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