Abstract
Abstract. Ozone (O3) plays an important role in chemical reactions and is usually incorporated in chemical data assimilation (DA). In tropical cyclones (TCs), O3 usually shows a lower concentration inside the eyewall and an elevated concentration around the eye, impacting meteorological as well as chemical variables. To identify the impact of O3 observations on TC structure, including meteorological and chemical information, we developed a coupled meteorology–chemistry DA system by employing the Weather Research and Forecasting model coupled with Chemistry (WRF-Chem) and an ensemble-based DA algorithm – the maximum likelihood ensemble filter (MLEF). For a TC case that occurred over East Asia, Typhoon Nabi (2005), our results indicate that the ensemble forecast is reasonable, accompanied with larger background state uncertainty over the TC, and also over eastern China. Similarly, the assimilation of O3 observations impacts meteorological and chemical variables near the TC and over eastern China. The strongest impact on air quality in the lower troposphere was over China, likely due to the pollution advection. In the vicinity of the TC, however, the strongest impact on chemical variables adjustment was at higher levels. The impact on meteorological variables was similar in both over China and near the TC. The analysis results are verified using several measures that include the cost function, root mean square (RMS) error with respect to observations, and degrees of freedom for signal (DFS). All measures indicate a positive impact of DA on the analysis – the cost function and RMS error have decreased by 16.9 and 8.87 %, respectively. In particular, the DFS indicates a strong positive impact of observations in the TC area, with a weaker maximum over northeastern China.
Highlights
The air quality forecast is related to emissions, transport, transformation and removal processes, and to the prevailing meteorological conditions
We focus on what is related to the tropical cyclones (TCs) formation and development, www.atmos-chem-phys.net/15/10019/2015/
We investigated the impact of ozone (O3) assimilation on the structure of a tropical cyclone (TC)
Summary
The air quality forecast is related to emissions, transport, transformation and removal processes, and to the prevailing meteorological conditions. Ozone (O3) has a relatively long photochemical lifetime and high concentrations at high latitude and in the stratosphere, except during ozone hole conditions It is a passive tracer at synoptic scale or smaller; variations of total column O3 in space and time are a result of the atmospheric flow, and is highly correlated to many meteorological vari-. The background error covariance represents the background state uncertainty (e.g., Buehner, 2005; Zupanski and Zupanski, 2007; Kim et al, 2010) These are estimated by taking the difference between the ensemble perturbation forecasts (total of 32) and the control forecast in the ensemble system (Zupanski, 2005; Zhang et al, 2013). Being calculated from the WRF-Chem ensemble forecast, the flow-dependent background error covariance is defined for meteorological and chemical variables, which allows chemistry observations to impact meteorological variables in DA. The background state uncertainties of NO2 and SO2 at 850 hPa (Fig. 2b and c, respectively) have more impact on central eastern China, implying no visible (or obvious) impact of the low-level NO2 and SO2 on the TC
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