Development of the Ensemble Navy Aerosol Analysis Prediction System (ENAAPS)  and its application of the Data Assimilation Research Testbed (DART) in  support of aerosol forecasting

Rubin, Juli I.; Reid, Jeffrey S.; Hansen, James A.; Anderson, Jeffrey L.; Collins, Nancy; Hoar, T. J.; Hogan, Timothy F.; Xian, Peng; McLay, Justin; Reynolds, C. A.; Sessions, W. R.; Westphal, Douglas L.; Zhang, Jianglong

doi:10.5194/acp-16-3927-2016

Cited by 61 publications

(66 citation statements)

References 78 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Various studies of AOP retrieval and aerosol simulation and assimilation have used the AERONET product for validation (Kinne et al, 2006;Levy et al, 2013;Sessions et al, 2015;Rubin et al, 2016). Because the AERONET product does not include AODs measured at 550 nm, we used the Ångström law to derive AODs at 550 nm from the AODs and Ångström exponents measured at multiple wavelengths (340-870 nm).…”

Section: Evaluation Dataset: the Aeronet Aodmentioning

confidence: 99%

JRAero: the Japanese Reanalysis for Aerosol v1.0

et al. 2017

View full text Add to dashboard Cite

Abstract. A global aerosol reanalysis product named the Japanese Reanalysis for Aerosol (JRAero) was constructed by the Meteorological Research Institute (MRI) of the Japan Meteorological Agency. The reanalysis employs a global aerosol transport model developed by MRI and a twodimensional variational data assimilation method. It assimilates maps of aerosol optical depth (AOD) from MODIS onboard the Terra and Aqua satellites every 6 h and has a TL159 horizontal resolution (approximately 1.1 • × 1.1 • ). This paper describes the aerosol transport model, the data assimilation system, the observation data, and the setup of the reanalysis and examines its quality with AOD observations.Comparisons with MODIS AODs that were used for the assimilation showed that the reanalysis showed much better agreement than the free run (without assimilation) of the aerosol model and improved under-and overestimation in the free run, thus confirming the accuracy of the data assimilation system. The reanalysis had a root mean square error (RMSE) of 0.05, a correlation coefficient (R) of 0.96, a mean fractional error (MFE) of 23.7 %, a mean fractional bias (MFB) of 2.8 %, and an index of agreement (IOA) of 0.98. The better agreement of the first guess, compared to the free run, indicates that aerosol fields obtained by the reanalysis can improve short-term forecasts.AOD fields from the reanalysis also agreed well with monthly averaged global AODs obtained by the Aerosol Robotic Network (AERONET) (RMSE = 0.08, R = 0.90, MFE = 28.1 %, MFB = 0.6 %, and IOA = 0.93). Site-by-site comparison showed that the reanalysis was considerably better than the free run; RMSE was less than 0.10 at 86.4 % of the 181 AERONET sites, R was greater than 0.90 at 40.7 % of the sites, and IOA was greater than 0.90 at 43.4 % of the sites. However, the reanalysis tended to have a negative bias at urban sites (in particular, megacities in industrializing countries) and a positive bias at mountain sites, possibly because of insufficient anthropogenic emissions data, the coarse model resolution, and the difference in representativeness between satellite and ground-based observations.

show abstract

Section: Evaluation Dataset: the Aeronet Aodmentioning

confidence: 99%

JRAero: the Japanese Reanalysis for Aerosol v1.0

et al. 2017

View full text Add to dashboard Cite

show abstract

“…Benedetti et al (2009) described the assimilation of AOD in the European Centre for Medium-Range Weather Forecasts (ECMWF) Integrated Forecasting System (IFS) using the 4-D-VAR method, while Yumimoto et al (2008) used the same approach to assimilate satellite lidar profiles in the RAMS/CFORS-4-D-VAR (RC4) model. Sequential assimilation approaches are also documented: optimal interpolation used by, for example, Collins et al (2001) and Rasch et al (2001) in the Model of Atmospheric Transport and Chemist (MATCH) and (Tombette et al, 2009) in the Polyphemus system; or the ensemble Kalman filter used by, for example, Sekiyama et al (2010) in the Model of Aerosol Species in the Global Atmosphere (MASINGAR), Schutgens et al (2010) in the SPRINTARS model, Pagowski and Grell (2012) in the WRF-Chem model, Dai et al (2014) in the Non-hydrostatic ICosahedral Atmospheric Model (NICAM) and Rubin et al (2016) in the Ensemble Navy Aerosol Analysis Prediction System/Data Assimilation Research Testbed (ENAAPS-DART) system.…”

Section: Introductionmentioning

confidence: 99%

Aerosol data assimilation in the chemical transport model MOCAGE during the TRAQA/ChArMEx campaign: aerosol optical depth

et al. 2016

View full text Add to dashboard Cite

Abstract. In this study, we describe the development of the aerosol optical depth (AOD) assimilation module in the chemistry transport model (CTM) MOCAGE (Modèle de Chimie Atmosphérique à Grande Echelle). Our goal is to assimilate the spatially averaged 2-D column AOD data from the National Aeronautics and Space Administration (NASA) Moderate-resolution Imaging Spectroradiometer (MODIS) instrument, and to estimate improvements in a 3-D CTM assimilation run compared to a direct model run. Our assimilation system uses 3-D-FGAT (first guess at appropriate time) as an assimilation method and the total 3-D aerosol concentration as a control variable. In order to have an extensive validation dataset, we carried out our experiment in the northern summer of 2012 when the pre-ChArMEx (CHemistry and AeRosol MEditerranean EXperiment) field campaign TRAQA (TRAnsport à longue distance et Qualité de l'Air dans le bassin méditerranéen) took place in the western Mediterranean basin. The assimilated model run is evaluated independently against a range of aerosol properties (2-D and 3-D) measured by in situ instruments (the TRAQA size-resolved balloon and aircraft measurements), the satellite Spinning Enhanced Visible and InfraRed Imager (SE-VIRI) instrument and ground-based instruments from the Aerosol Robotic Network (AERONET) network. The evaluation demonstrates that the AOD assimilation greatly improves aerosol representation in the model. For example, the comparison of the direct and the assimilated model run with AERONET data shows that the assimilation increased the correlation (from 0.74 to 0.88), and reduced the bias (from 0.050 to 0.006) and the root mean square error in the AOD (from 0.12 to 0.07). When compared to the 3-D concentration data obtained by the in situ aircraft and balloon measurements, the assimilation consistently improves the model output. The best results as expected occur when the shape of the vertical profile is correctly simulated by the direct model. We also examine how the assimilation can influence the modelled aerosol vertical distribution. The results show that a 2-D continuous AOD assimilation can improve the 3-D vertical profile, as a result of differential horizontal transport of aerosols in the model.

show abstract

“…The traditional EnKF with perturbed observations was initially applied to severe dust storm forecasts over China by assimilating the surface particulate matter (PM) 10 observations to correct the dust ICs once a day, and the results proved that the EnKF could calculate the flow‐dependent B , which generally was not expected in other traditional assimilation techniques (Lin et al, ). Compared with the traditional EnKF, the ensemble adjustment Kalman filter (Anderson, ; Whitaker & Hamill, ) was applied to assimilate bias‐corrected MODIS AOTs every 6 hr in Navy ensemble‐based aerosol forecasts and data assimilation systems, and the ensemble system was better able to capture sharp gradients in aerosol features than the 2DVAR system (Rubin et al, ; Rubin et al, ). The local ensemble transform Kalman filter (LETKF) assimilates observations within a spatially physical local volume at each model grid point simultaneously and does not require an orthogonal basis (Miyoshi et al, ), which significantly enhances the computational efficiency with parallel implementation (Hunt et al, ).…”

Section: Introductionmentioning

confidence: 99%

Hourly Aerosol Assimilation of Himawari‐8 AOT Using the Four‐Dimensional Local Ensemble Transform Kalman Filter

Dai

Cheng

Suzuki

et al. 2019

J Adv Model Earth Syst

View full text Add to dashboard Cite

The next‐generation geostationary satellite Himawari‐8 has a much higher observation frequency of the aerosol field than polar‐orbiting satellites. Aerosol analyses with a geostationary satellite can advance our understanding of the rapid spatiotemporal evolution of aerosols, which is especially critical for studies of air pollution and its mechanisms. We present a one‐monthlong hourly aerosol analysis using an aerosol data assimilation based on the local ensemble Kalman filter (LETKF), Himawari‐8‐retrieved hourly aerosol optical thicknesses (AOTs), and a global model named Non‐hydrostatic Icosahedral Atmospheric Model coupled with an aerosol model named Spectral Radiation Transport Model for Aerosol Species (NICAM‐SPRINTARS). To assimilate asynchronous observations and avoid frequent switching between the assimilation and ensemble aerosol forecasts, the LETKF is also extended to the four‐dimensional LETKF (4D‐LETKF). The hourly aerosol analyses are evaluated with both the assimilated Himawari‐8 AOTs and independent Moderate Resolution Imaging Spectroradiometer (MODIS)‐ and AErosol RObotic NETwork (AERONET)‐retrieved AOTs. All evaluations show that the assimilations positively affect the model performances and produce simulated AOTs that are closer to the observations. The analyses correctly reduce the significantly positive biases and root‐mean‐square errors of the control experiment, especially over East China and Australia. Our results also show that hourly aerosol analyses with more frequent Himawari‐8 observations are superior to those using the polar satellite MODIS observations. The performances among the LETKF and 4D‐LETKF experiments are generally not so different, but the computational load of the 4D‐LETKF is much lighter than that of the LETKF.

show abstract

Development of the Ensemble Navy Aerosol Analysis Prediction System (ENAAPS) and its application of the Data Assimilation Research Testbed (DART) in support of aerosol forecasting

Cited by 61 publications

References 78 publications

JRAero: the Japanese Reanalysis for Aerosol v1.0

JRAero: the Japanese Reanalysis for Aerosol v1.0

Aerosol data assimilation in the chemical transport model MOCAGE during the TRAQA/ChArMEx campaign: aerosol optical depth

Hourly Aerosol Assimilation of Himawari‐8 AOT Using the Four‐Dimensional Local Ensemble Transform Kalman Filter

Contact Info

Product

Resources

About