Abstract
AbstractA realistic simulation of the atmospheric boundary layer (ABL) depends on an accurate representation of the land–atmosphere coupling. Land surface temperature (LST) plays an important role in this context and the assimilation of LST can lead to improved estimates of the boundary layer and its processes. We assimilated synthetic satellite LST retrievals derived from a nature run as truth into a fully coupled, state‐of‐the‐art land–atmosphere numeric weather prediction model. As assimilation system a local ensemble transform Kalman filter was used and the control vector was augmented by the soil temperature and humidity. To evaluate the concept of the augmented control vector, two‐day case‐studies with different control vector settings were conducted for clear‐sky periods in March and August 2017. These experiments with hourly LST assimilation were validated against the nature run and overall, the RMSE of atmospheric and soil temperature of the first‐guess (and analysis) were reduced. The temperature estimate of the ABL was particularly improved during daytime as was the estimate of the soil temperature during the whole diurnal cycle. The best impact of LST assimilation on the soil and the ABL was achieved with the augmented control vector. Through the coupling between the soil and the atmosphere, the assimilation of LST can have a positive impact on the temperature forecast of the ABL even after 15 hr because of the memory of the soil. These encouraging results motivate further work towards the assimilation of real satellite LST retrievals.
Highlights
The coupling between soil and atmosphere plays an important role for atmospheric boundary layer (ABL) development (Koster et al, 2006; Holtslag et al, 2007; Sandu et al., 2013)
To see how the augmented COnsortium for Small-scale MOdelling (COSMO)-Kilometre-scale ENsemble Data Assimilation scheme (KENDA) system works and how the effect of land surface temperature (LST) assimilation varies during the diurnal cycle, the Single-Observation Experiments (SOEs) were carried out on 27 March and 29 August at 0000 UTC (0200 h local time) and 1200 UTC (1400 h local time)
To see how the effect of LST assimilation varies during the diurnal cycle, the SOEs were performed day and night
Summary
The coupling between soil and atmosphere plays an important role for atmospheric boundary layer (ABL) development (Koster et al, 2006; Holtslag et al, 2007; Sandu et al., 2013). A realistic simulation of the ABL needs an accurate representation of the thermal coupling and the surface processes (Reichle et al, 2010; Bosveld et al, 2014; Trigo et al, 2015). It is well-known that the energy budget. Wileyonlinelibrary.com/journal/qj 3980 at the surface depends on long- and short-wave radiation, sensible and latent heat flux, and soil heat flux. LST plays a role in the partitioning of sensible and latent heat flux and determines the upward thermal radiation. Improving the representation of LST in atmospheric simulations has the potential to further enhance the representation of variables and fluxes that are correlated with LST (Bosilovich et al, 2007; Santanello et al, 2013; Trigo et al, 2015; Candy et al, 2017)
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