Abstract
Errors in soil moisture adversely impact the modeling of land–atmosphere water and energy fluxes and, consequently, near-surface atmospheric conditions in atmospheric data assimilation systems (ADAS). To mitigate such errors, a land surface analysis is included in many such systems, although not yet in the currently operational NASA Goddard Earth Observing System (GEOS) ADAS. This article investigates the assimilation of L-band brightness temperature (Tb) observations from the Soil Moisture Active Passive (SMAP) mission in the GEOS weakly coupled land–atmosphere data assimilation system (LADAS) during boreal summer 2017. The SMAP Tb analysis improves the correlation of LADAS surface and root-zone soil moisture versus in situ measurements by ~0.1–0.26 over that of ADAS estimates; the unbiased root-mean-square error of LADAS soil moisture is reduced by 0.002–0.008 m3/m3 from that of ADAS. Furthermore, the global land average RMSE versus in situ measurements of screen-level air specific humidity (q2m) and daily maximum temperature (T2mmax) is reduced by 0.05 g/kg and 0.04 K, respectively, for LADAS compared to ADAS estimates. Regionally, the RMSE of LADAS q2m and T2mmax is improved by up to 0.4 g/kg and 0.3 K, respectively. Improvement in LADAS specific humidity extends into the lower troposphere (below ~700 mb), with relative improvements in bias of 15–25%, although LADAS air temperature bias slightly increases relative to that of ADAS. Finally, the root mean square of the LADAS Tb observation-minus-forecast residuals is smaller by up to ~0.1 K than in a land-only assimilation system, corroborating the positive impact of the Tb analysis on the modeled land–atmosphere coupling.
Highlights
SOIL moisture plays an important role in the Earth’s energy, water, and carbon cycles through its control on photosynthesis and evapotranspiration, which in turn impact atmospheric boundary layer dynamics
Since here the land data assimilation system (LDAS) is used within the coupled land-atmosphere data assimilation system (LADAS), at a different resolution, and in the Catchment model’s cube-sphere tile space, this section confirms the proper functioning of the LDAS subsystem by briefly examining the Tb residuals and the resulting soil moisture analysis increments
Whereas OmF residuals provide independent verification of the model forecast Tb, OmA residuals are computed by differencing a Soil Moisture Active Passive (SMAP) Tb observation and a model forecast that was informed by this very observation
Summary
SOIL moisture plays an important role in the Earth’s energy, water, and carbon cycles through its control on photosynthesis and evapotranspiration, which in turn impact atmospheric boundary layer dynamics. The accurate modeling of soil moisture is critical for improving weather and seasonal climate predictions [1]-[5]. Soil moisture processes and land-atmosphere interactions are highly complex and heterogeneous, and current models are subject to large uncertainties [6]. Near-surface air temperature and humidity are sensitive to soil moisture under certain atmospheric conditions. Since the 1990s, many weather centers have been using screen-level (2-m) temperature and humidity measurements to constrain the simulated soil moisture and thereby improve medium-range forecasts of near-surface temperature and precipitation in their operational data assimilation systems [8]-[16]
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