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Reducing Vertical Transport Over Complex Terrain in Photochemical Grid Models

Reducing Vertical Transport Over Complex Terrain in Photochemical Grid Models. Chris Emery, Ed Tai, Ralph Morris, Greg Yarwood ENVIRON International Corporation Novato, California 8 th Annual CMAS Conference Chapel Hill, NC October 20, 2009. Introduction.

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Reducing Vertical Transport Over Complex Terrain in Photochemical Grid Models

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  1. Reducing Vertical TransportOver Complex Terrain inPhotochemical Grid Models Chris Emery, Ed Tai, Ralph Morris, Greg Yarwood ENVIRON International Corporation Novato, California 8th Annual CMAS Conference Chapel Hill, NC October 20, 2009

  2. Introduction • Regional photochemical models over predict springtime ozone throughout the inter-mountain western U.S. • CMAQ: 2002 WRAP • CAMx: 2005 FCAQTF • Typically ~20 ppb higher than remote measurements • Results from stratospheric ozone levels in top model layer • Enters CMAQ/CAMx via lateral boundary conditions (BCs) • Derived from output of GEOS-CHEM global chemistry model • Stratospheric ozone is too efficiently transported to surface over complex/high terrain • Rockies, Sierras, Cascades

  3. Introduction 2002 CMAQ Annual Max Daily 8-hour Ozone

  4. Introduction • WRAP CMAQ and FCAQTF CAMx runs use 19 layers • Top layer spans 8-15 km • 3 to 5 layers above PBL • MM5 run for 34 layers • WRAP CMAQ and FCAQTF CAMx runs use 2002 BCs • Ozone in layer 19 range 100-300 ppb

  5. Introduction • Contributors to high ozone over the Rockies: • High surface altitudes (2-3 km MSL) • Surface is closer to stratosphere • Deep PBL mixing and convection (through 4-6 km MSL) • Couple surface to mid-troposphere • Vigorous resolved vertical circulations (through 4-8 km MSL) • Transport layer 19 ozone downward • Solutions we’ve identified in this study: • Coarse vertical grid structure (more aloft layers help) • GEOS-CHEM BC interface (improved interpolation helps) • Vertical advection technique (alternative approach helps)

  6. Approach • Test bed: CAMx 2005 FCAQTF application • Inert, ozone only, no sources/sinks • Single 12-km regional grid covering western U.S. • Track ozone IC/BC over April 2005 • Original IC/BC from 2002 GEOS-CHEM extraction (WRAP) • New IC/BC from 2005 GEOS-CHEM extraction • Test and evaluate several ideas: • Modify input wind fields (smoothers, filters, etc.) • Improve treatment of CAMx top boundary condition • Test alternative vertical grid structures/resolution • Improve GEOS-CHEM interface technique • Modify CAMx vertical advection solver

  7. Modify Input Winds • Original Rationale • Vertical velocity derived from input horizontal winds • CAMx and CMAQ “yamo” approaches are similar • Filter strong divergences in input winds to calm vertical velocity • Apply aggressively to upper layers only • Test on 19-layer structure and compare to un-modified case • Three approaches were investigated • Smoother-desmoother approach of Yang and Chen (2008) • Divergence minimization from CALMET (Scire et al., 2000) • Mass filter of Rotman et al. (2004)

  8. Modify Input Winds • Results • Minor (~10 ppb) reductions in peak April ozone • Troubling effects on vertical velocity profiles in upper layers • CAMx surface ozone reductions not caused by improved vertical advection • Instead by artificial dilution of top layer ozone • Caused by CAMx arbitrary top boundary condition (70 ppb) • CAMx was revised to use “zero-gradient” top boundary conditions for all subsequent tests • Top BC assigned from top layer concentration (a la CMAQ) • Removes artificial dilution of top layer • BUT increases surface ozone

  9. More Model Layers • Reprocess input meteorology, no smoothers/filters • Zero-gradient top boundary condition • Full 34 MM5 layer structure • Runs ~2x slower than 19 layers, 10-15 ppb ozone reduction • Intermediate 22 layers to improve resolution aloft • Runs ~1.1x slower than 19 layers, ~10 ppb ozone reduction 19-layer 22-layer 34-layer

  10. 2005 Day-Specific BCs • New 2005 GEOS-CHEM BCs recently became available • Zero-gradient top boundary condition • Much higher stratospheric ozone (occasionally ~1000 ppb) • Higher surface ozone, different spatial patterns • NOTE CHANGES TO COLOR SCALE! 19-layer 22-layer 34-layer

  11. 2005 Day-Specific BCs • Issues found in GEOS-CHEM interface program • High ozone bias in topmost layers for coarse vertical layer structures • We improved the vertical layer-weighting technique • Figure below shows new ozone profiles

  12. Improved 2005 BCs • Improved vertical weighting technique • Zero-gradient top boundary condition • Lower stratospheric ozone, lower surface ozone • Ozone still higher than with 2002 BCs • NOTE CHANGES TO COLOR SCALE! 19-layer 22-layer 34-layer

  13. Revised Vertical Advection • Revised vertical velocity calculation to remove downward bias • Revised vertical solver to be consistent • Zero-gradient top BC, improved lateral BC • 40-70 ppb reduction in April maximum ozone 19-layer BASE MODIFIED ADVECTION

  14. Revised Vertical Advection • Comparison of 19, 22, and 34-layer configurations • NOTE CHANGES TO COLOR SCALE! 19-layer 22-layer 34-layer

  15. Full Photochemical Run • Run CAMx on 36/12/4-km FCAQTF grids for April and July 2005 • Compare 3 runs: • Original 19-layer, 2002 BCs*, original vertical advection • New 22-layer, 2005 BCs, original vertical advection • New 22-layer, 2005 BCs, revised vertical advection • Look at monthly maximum 8-hour ozone fields on 12 and 4 km grids *2002 BCs: stratospheric ozone levels removed in layer 19

  16. Full Photochemical RunApril 2005, 4-km Grid 19-layer 22-layer 22-layer 2002 BCs 2005 BCs 2005 BCs Orig CAMx Orig CAMx Revised CAMx

  17. Full Photochemical RunApril 2005, 12-km Grid 19-layer 22-layer 22-layer 2002 BCs 2005 BCs 2005 BCs Orig CAMx Orig CAMx Revised CAMx

  18. Full Photochemical RunJuly 2005, 4-km Grid 19-layer 22-layer 22-layer 2002 BCs 2005 BCs 2005 BCs Orig CAMx Orig CAMx Revised CAMx

  19. Full Photochemical RunJuly 2005, 12-km Grid 19-layer 22-layer 22-layer 2002 BCs 2005 BCs 2005 BCs Orig CAMx Orig CAMx Revised CAMx

  20. On-Going Work • Additional testing of modified CAMx for full photochemical/PM applications • Complete 2005 FCAQTF Application; evaluate ozone and PM • O&G projects in Rocky Mountains • Denver SIP modeling • CMAQ exhibits similar problems • EPA/ORD is working on a vertical advection modification • See Young, Pleim, Mathur poster • Interact with ORD and OAQPS • Test improvements using a western U.S. CMAQ database

  21. Acknowledgement • The authors acknowledge funding support from the American Petroleum Institute (API) • Questions…

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