Aerosol long term simulation using TCAM model

1. Aerosol long term simulation using TCAM model C. Carnevale, G. Finzi, E. Pisoni, M. Volta Department for Electronics and Automation University of Brescia

2. Index • The GAMES modelling system • The Transport Chemical Aerosol Model • The CityDelta III base case simulation • Chemical composition of simulated PM10 • Conclusion

3. The Gas Aerosol Modelling Evaluation System (GAMES) Emission inventories Land use Topography MM5 output Meterological Pre-processor Emission Model Temporal Profiles 3D wind and temperature fields Turbolence and Boundary Layer parameters Emission Fields Initial and Boundary condition Pre-processors Boundary and Initial condition TCAM VOC speciation Profiles 3D concentration fields Continental model output SystemEvaluation Tool

4. TCAM (Transport and Chemical Aerosol Model):Transport and Depostion Module • Eulerian 3D model • Terrain-following co-ordinate system • Horizontal Transport Module: chapeau function + forester filter • Vertical Transport Module: Crank-Nicholson hybrid solver based on the vertical diffusivity coefficient • Deposition Module • Dry deposition: resistance-based approach • Wet deposition: scavenging approach for both gas and aerosol species

5. Species: 95 • Reactions: 187 • Fast-Species (12): LSODE (implicit) • Slow-Species: Adams-Bashforth (explicit) TCAM (Transport and Chemical Aerosol Model):Gas chemical module • Chemical Mechanism • CBIV 90 • SAPRC 90/97 • COCOH 97 • Numerical Solver • QSSA (explicit) • IEH (hybrid)

6. Shell Core TCAM (Transport and Chemical Aerosol Model):Aerosol module • Chemical Species: 21 • 12 inorganics • 9 organics • Size Classes: 10 (da 0.01 mm a 50 mm) • Fixed moving approach • Involved Phenomena: • Condensation/Evaporation • Nucleation • SO2 aqueus chemistry

7. CDIII base case simulation: computational domain • 300x300 km2 • Horizontal resolution: 5x5 km2 • Vertical resolution: 11 varying thickness levels • 1st level: 20m • Simulation year: 2004

8. CDIII base case simulation: Gas emission fields VOC NH3 NOx SOx

9. CDIII base case simulation:PM emission fields PM10 PM2.5

10. CDIII base case simulation:Monitoring station

11. CDIII base case simulation:Yearly Performance 95th Perc Mean Correlation NBIAS

12. CDIII base case simulation:Winter Performances 95th Perc Mean Correlation NBIAS

13. CDIII base case simulation:Summer Performances 95th Perc Mean Correlation NBIAS

14. CDIII base case simulation:PM10 concentration maps Year Winter Summer

15. CDIII base case simulation:PM10 yearly chemical composition

16. CDIII base case simulation:mainly inorganic fraction maps NO3- NH4+

17. Conclusion • Quite good performance in terms of mean values both in winter and summer; • Correlation lower than 0.65 in all the station • CAUSES? • TCAM reproduces reasonably the chemical composition of PM10 • overestimation of ammonium fraction

18. Emission pre-processor (UNIBS) POllutant Emission Model for CDIII (POEM-CDIII) provides hourly base case and scenario emission fields for: CAMx TCAM CESI AMA JRC data Chemical/Sizecharacterization Chemicalcharacterization Time modulation Gas: CBIV99 PM: 2 size bins, 8 chemical species Gas: COCOH97 PM: 6 size bins, 8 chemical species

19. Boundary pre-processor (CESI) • Boundy Module provides hourly base case and scenario boundary conditions TCAM Gas: 62 species PM: 10 size bins 21 chemical species Chimere Gas: 23 species PM: 4 size bins 11 chemical species BOUNDY PM experimental size profiles

20. CDIII base case simulation:PM2.5/PM10 concentration map PM2.5/PM10 Emisison PM2.5/PM10 Concentration