33 research outputs found
Evaluation of the high resolution WRF-Chem (v3.4.1) air quality forecast and its comparison with statistical ozone predictions
An integrated modelling system based on the regional online coupled
meteorology–atmospheric chemistry WRF-Chem model configured with two nested
domains with horizontal resolutions of 11.1 and 3.7 km has been applied for
numerical weather prediction and for air quality forecasts in Slovenia. In the
study, an evaluation of the air quality forecasting system has been performed
for summer 2013. In the case of ozone (O3) daily maxima, the first- and
second-day model predictions have been also compared to the operational
statistical O3 forecast and to the persistence. Results of discrete and
categorical evaluations show that the WRF-Chem-based forecasting system is
able to produce reliable forecasts which, depending on monitoring site and
the evaluation measure applied, can outperform the statistical model. For
example, the correlation coefficient shows the highest skill for WRF-Chem
model O3 predictions, confirming the significance of the non-linear
processes taken into account in an online coupled Eulerian model. For some
stations and areas biases were relatively high due to highly complex terrain
and unresolved local meteorological and emission dynamics, which contributed
to somewhat lower WRF-Chem skill obtained in categorical model evaluations.
Applying a bias correction could further improve WRF-Chem model forecasting
skill in these cases
Evaluation of the high resolution WRF-Chem (v3.4.1) air quality forecast and its comparison with statistical ozone predictions
An integrated modelling system based on the regional online coupled
meteorology–atmospheric chemistry WRF-Chem model configured with two nested
domains with horizontal resolutions of 11.1 and 3.7 km has been applied for
numerical weather prediction and for air quality forecasts in Slovenia. In the
study, an evaluation of the air quality forecasting system has been performed
for summer 2013. In the case of ozone (O3) daily maxima, the first- and
second-day model predictions have been also compared to the operational
statistical O3 forecast and to the persistence. Results of discrete and
categorical evaluations show that the WRF-Chem-based forecasting system is
able to produce reliable forecasts which, depending on monitoring site and
the evaluation measure applied, can outperform the statistical model. For
example, the correlation coefficient shows the highest skill for WRF-Chem
model O3 predictions, confirming the significance of the non-linear
processes taken into account in an online coupled Eulerian model. For some
stations and areas biases were relatively high due to highly complex terrain
and unresolved local meteorological and emission dynamics, which contributed
to somewhat lower WRF-Chem skill obtained in categorical model evaluations.
Applying a bias correction could further improve WRF-Chem model forecasting
skill in these cases
Regional effects of atmospheric aerosols on temperature: An evaluation of an ensemble of online coupled models
The climate effect of atmospheric aerosols is associated with their
influence on the radiative budget of the Earth due to the direct
aerosol–radiation interactions (ARIs) and indirect effects, resulting from
aerosol–cloud–radiation interactions (ACIs). Online coupled
meteorology–chemistry models permit the description of these effects on the
basis of simulated atmospheric aerosol concentrations, although there is
still some uncertainty associated with the use of these models. Thus,
the objective of this work is to assess whether the inclusion of atmospheric
aerosol radiative feedbacks of an ensemble of online coupled models improves
the simulation results for maximum, mean and minimum temperature at 2 m over
Europe. The evaluated models outputs originate from EuMetChem COST Action
ES1004 simulations for Europe, differing in the inclusion (or omission) of
ARI and ACI in the various models. The cases studies cover two important
atmospheric aerosol episodes over Europe in the year 2010: (i) a heat wave event
and a forest fire episode (July–August 2010) and (ii) a more humid episode
including a Saharan desert dust outbreak in October 2010. The simulation
results are evaluated against observational data from the E-OBS gridded database.
The results indicate that, although there is only a slight improvement in the
bias of the simulation results when including the radiative feedbacks, the
spatiotemporal variability and correlation coefficients are improved for the
cases under study when atmospheric aerosol radiative effects are included
An assessment of aerosol optical properties from remote-sensing observations and regional chemistry–climate coupled models over Europe
Atmospheric aerosols modify the radiative budget
of the Earth due to their optical, microphysical and chemical properties, and
are considered one of the most uncertain climate forcing agents. In order to
characterise the uncertainties associated with satellite and modelling
approaches to represent aerosol optical properties, mainly aerosol optical
depth (AOD) and Ångström exponent (AE), their representation by
different remote-sensing sensors and regional online coupled
chemistry–climate models over Europe are evaluated. This work also
characterises whether the inclusion of aerosol–radiation (ARI) or/and
aerosol–cloud interactions (ACI) help improve the skills of modelling
outputs.Two case studies were selected within the EuMetChem COST Action ES1004
framework when important aerosol episodes in 2010 all over Europe took
place: a Russian wildfire episode and a Saharan desert dust outbreak that
covered most of the Mediterranean Sea. The model data came from different
regional air-quality–climate simulations performed by working group 2 of
EuMetChem, which differed according to whether ARI or ACI was included or
not. The remote-sensing data came from three different sensors: MODIS, OMI
and SeaWIFS. The evaluation used classical statistical metrics to first
compare satellite data versus the ground-based instrument network (AERONET)
and then to evaluate model versus the observational data (both satellite and
ground-based data).Regarding the uncertainty in the satellite representation of AOD, MODIS
presented the best agreement with the AERONET observations compared to other
satellite AOD observations. The differences found between remote-sensing
sensors highlighted the uncertainty in the observations, which have to be
taken into account when evaluating models. When modelling results were
considered, a common trend for underestimating high AOD levels was observed.
For the AE, models tended to underestimate its variability, except when
considering a sectional approach in the aerosol representation. The modelling
results showed better skills when ARI+ACI interactions were included; hence
this improvement in the representation of AOD (above 30 % in the model error)
and AE (between 20 and 75 %) is important to provide a better description of
aerosol–radiation–cloud interactions in regional climate models
Sensitivity of feedback effects in CBMZ/MOSAIC chemical mechanism
To investigate the impact of the aerosol effects on meteorological variables and pollutant concentrations two simulations with the WRF-Chem model have been performed over Europe for year 2010. We have performed a baseline simulation without any feedback effects and a second simulation including the direct as well as the indirect aerosol effect. The paper describes the full configuration of the model, the simulation design, special impacts and evaluation. Although low aerosol particle concentrations are detected, the inclusion of the feedback effects results in an increase of solar radiation at the surface over cloudy areas (North-West, including the Atlantic) and decrease over more sunny locations (South-East). Aerosol effects produce an increase of the water vapor and decrease the planet boundary layer height over the whole domain except in the Sahara area, where the maximum particle concentrations are detected. Significant ozone concentrations are found over the Mediterranean area. Simulated feedback effects between aerosol concentrations and meteorological variables and on pollutant distributions strongly depend on the aerosol concentrations and the clouds. Further investigations are necessary with higher aerosol particle concentrations. WRF-Chem variables are evaluated using available hourly observations in terms of performance statistics. Standardized observations from the ENSEMBLE system web-interface were used. The research was developed under the second phase of Air Quality Model Evaluation International Initiative (AQMEII). WRF-Chem demonstrates its capability in capturing temporal and spatial variations of the major meteorological variables and pollutants, except the wind speed over complex terrain. The wind speed bias may affect the accuracy in the chemical predictions (NO2, SO2). The analysis of the correlations between simulated data sets and observational data sets indicates that the simulation with aerosol effects performs slightly better. These results indicate potential importance of the aerosol feedback effects and an urgent need to further improve the representations in current atmospheric models to reduce uncertainties at all scales
Analysis of meteorology-chemistry interactions during air pollution episodes using online coupled models within AQMEII Phase-2
This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/3.0/).This study reviews the top ranked meteorology and chemistry interactions in online coupled models recommended by an experts’ survey conducted in COST Action EuMetChem and examines the sensitivity of those interactions during two pollution episodes: the Russian forest fires 25 Jul -15 Aug 2010 and a Saharan dust transport event from 1 Oct -31 Oct 2010 as a part of the AQMEII phase-2 exercise. Three WRF-Chem model simulations were performed for the forest fire case for a baseline without any aerosol feedback on meteorology, a simulation with aerosol direct effects only and a simulation including both direct and indirect effects. For the dust case study, eight WRF-Chem and one WRF-CMAQ simulations were selected from the set of simulations conducted in the framework of AQMEII. Of these two simulations considered no feedbacks, two included direct effects only and five simulations included both direct and indirect effects. The results from both episodes demonstrate that it is important to include the meteorology and chemistry interactions in online-coupled models. Model evaluations using routine observations collected in AQMEII phase-2 and observations from a station in Moscow show that for the fire case the simulation including only aerosol direct effects has better performance than the simulations with no aerosol feedbacks or including both direct and indirect effects. The normalized mean biases are significantly reduced by 10-20% for PM10 when including aerosol direct effects. The analysis for the dust case confirms that models perform better when including aerosol direct effects, but worse when including both aerosol direct and indirect effects, which suggests that the representation of aerosol indirect effects needs to be improved in the model.Peer reviewedFinal Published versio