Abstract
Abstract. The wind extraction due to assimilation of stratospheric trace gas (tracer) data is examined using a 4D-Var (four-dimensional variational) data assimilation system based on the shallow water equations coupled to the tracer continuity equation. The procedure is outlined as follows. First, a nature run is created, simulating middle stratospheric winter conditions. Second, ozone (O3), nitrous oxide (N2O), and water vapor (H2O) (treated in this study as passive tracers) are initialized using Aura Microwave Limb Sounder (MLS) mixing ratios at 850 K potential temperature and are advected by the nature run winds. Third, the initial dynamical conditions are perturbed by using a 6 h offset. Fourth, simulated hourly tracer observations on the full model grid are assimilated with a 4D-Var system in which tracer and winds are coupled via the adjoint of the tracer continuity equation. Multiple assimilation experiments are performed by varying the amount of random observation error added to the simulated measurements. Finally, the wind extraction potential (WEP) is calculated as the reduction of the vector wind root mean square error (RMSE) relative to the maximum possible reduction. For a single 6 h assimilation cycle with the smallest observation error, WEP values are ~60% for all three tracers, while 10-day multi-cycle simulations result in WEP of ~90%, wind errors of ~0.3 m s−1, and height errors of ~13 m. There is therefore sufficient information in the tracer fields to almost completely constrain the dynamics, even without direct assimilation of dynamical information. When realistic observation error is added (based on MLS precisions at 10 hPa), the WEP after 10 days is 90% for O3, 87% for N2O, and 72% for H2O. O3 and N2O provide more wind information than H2O due to stronger background gradients relative to the MLS precisions. The RMSE for wind reach a minimum level of ~0.3–0.9 m s−1 for the MLS precisions, suggesting a limit to which realistic tracers could constrain the winds, given complete global cover age. With higher observation noise levels, the WEP values decrease, but the impact on the winds is still positive up to noise levels of 100% (relative to the global mean value) when compared to the case of no data assimilation.
Highlights
This study examines the problem of extraction of global wind information from the assimilation of stratospheric trace gas observations
A 4D-Var data assimilation system based on a global shallow water model coupled to a tracer advection equation was used to examine the tracer–wind coupling problem in a highly idealized setting
While a number of additional tracers could have been tested, we focused on O3, N2O, and H2O, which are readily available from instruments such as Microwave Limb Sounder (MLS)
Summary
This study examines the problem of extraction of global wind information from the assimilation of stratospheric trace gas (tracer) observations. The assimilation of stratospheric ozone in 4D-Var (four-dimensional variational) algorithms and the resultant dynamical coupling have previously caused problems in operational numerical weather prediction (NWP) (Han and McNally, 2010; Dragani and McNally, 2013). Among the tracer assimilation challenges are paucity of observations, insufficient data quality, insufficient modeling of tracers in the forecast model, as well as phenomenological limitations due to tracer variations with respect to the wind vector. The basic conclusion is that with complete data coverage, sufficient precision, a high-quality background tracer field, and a 4D-Var or extended Kalman filter algorithm, wind extraction is possible across the globe and throughout the stratosphere and upper troposphere. The ability to extract wind is greatly hindered by limitations in any of these
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