Air quality forecasting in an urban area at high spatial resolution

Air quality forecasting systems can contribute to the eventual improvement of atmospheric quality on regional or urban scales and to reduce the risk of people being exposed to high air pollutant levels. PM2.5 is one of the most important air pollutants that can penetrate deep into our lungs causing...

Πλήρης περιγραφή

Λεπτομέρειες βιβλιογραφικής εγγραφής
Κύριος συγγραφέας: Σιούτη, Ευαγγελία
Άλλοι συγγραφείς: Siouti, Evangelia
Γλώσσα:English
Έκδοση: 2023
Θέματα:
Διαθέσιμο Online:https://hdl.handle.net/10889/25160
Περιγραφή
Περίληψη:Air quality forecasting systems can contribute to the eventual improvement of atmospheric quality on regional or urban scales and to reduce the risk of people being exposed to high air pollutant levels. PM2.5 is one of the most important air pollutants that can penetrate deep into our lungs causing premature deaths, cardiovascular and respiratory problems, but also can damage ecosystems. Gas-phase pollutants such as O3 and NOx have also a negative effect on human health causing lung diseases. Air pollution forecasting systems are becoming an increasingly useful tool, as they can predict the future status of the atmosphere and potentially prevent human health risks. The air quality forecasting system that we have developed called SmartAQ (Smart Air Quality), combines state-of-the-art meteorological and chemical transport models to produce high-resolution predictions of 1x1 km2 for an urban area for the next 3-day period. The system simulates the air pollution in Europe using 36x36 km2 spatial resolution and through three nested grids with increasing resolution it focuses on the urban area of interest with 1x1 km2 resolution. The WRF (Weather Research and Forecasting) model prepares high-resolution predictions of meteorology, the MEGAN (Model of Emissions of Gases and Aerosols from Nature) model provides aerosol and gas-phase emissions and the chemical transport model PMCAMx (Particulate Matter Comprehensive Air quality Model with extensions) is used to simulate air quality. The PSAT (Particulate matter Source Apportionment Technology) algorithm is used together with PMCAMx to determine the source contributions for each pollutant for the urban area. SmartAQ operates automatically, in real-time and predicts the pollutant concentration of tens of gases (NOx, SO2, CO, O3, volatile organic compounds, etc.), the complete aerosol size and chemical composition together with PM1, PM2.5 and PM10 levels and the pollutant sources. The urban area of Patras in Greece was used for the first application of our system due to high-dense network of low-cost sensors that measure PM2.5 concentrations in the city. Field measurements have indicated that cooking and residential biomass burning sources are of primary importance in urban areas, but the corresponding emissions are often neglected or underestimated by emission inventories and chemical transport models leading to uncertain air quality predictions. In Patras, wood burning in fireplaces is the dominant source of pollution during wintertime, while cooking is the most important local source of pollution during the summer and especially during the nighttime based on field measurements. For these reasons, bottom-up inventories for cooking and residential biomass burning were developed at 1x1 km2 resolution for the city of Patras. The spatial distribution of cooking emissions was based on the exact location of restaurants in the city and the temporal distribution on measured cooking OA diurnal profile. The spatial distribution of residential biomass burning emissions was based on the density of houses in the urban area and the temporal patterns on field measurements. Biomass burning organic aerosols were considered volatile and chemically reactive and their emissions were temperature dependent. PMCAMx reproduced well the PM2.5 concentrations for the area of high cooking OA emissions, while it tended to overestimate the PM2.5 concentrations for the outskirts of the city. During the wintertime, the model reproduced the measured PM2.5 profile in the high-biomass-burning-emission area, but it tended to overpredict PM2.5 in the suburbs. Driving variables for the discrepancies between model and measurements were uncertainties in cooking and biomass burning OA emissions, errors in meteorology and uncertainties in the low-cost sensor measurements used for the evaluation. The overprediction at the outskirts was probably due to overestimation of regional pollution. SmartAQ predicted for PM2.5 that cooking was the dominant local source of pollution during summer and biomass burning for residential heating was the dominant one during winter, which are consistent with measurements. The developed air quality forecasting system can be applied to any European urban area to produce high resolution atmospheric and weather predictions.