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Evaluation of CAMx: Issues Related to Sectional Models. Ralph Morris, Bonyoung Koo, Steve Lau and Greg Yarwood ENVIRON International Corporation Novato, CA ( rmorris@environcorp.com ) Chao-Jung Chien, Gail Tonnesen and Zion Wang UCR CE-CERT PM Model Performance Workshop
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Evaluation of CAMx: Issues Related to Sectional Models Ralph Morris, Bonyoung Koo, Steve Lau and Greg Yarwood ENVIRON International Corporation Novato, CA (rmorris@environcorp.com) Chao-Jung Chien, Gail Tonnesen and Zion Wang UCR CE-CERT PM Model Performance Workshop Research Triangle Park, North Carolina February 10-11, 2004
Outline • Development of CAMx4+ that combines CAMx4 with PMCAMx • Mechanism 4 (M4) 2-Section treatment (fine/coarse) • PMCAMx N-Section treatment • Effects of sectional treatment on nitrate in SoCal • Multi-Model Intercomparison using WUSA 1996 • CMAQ, REMSAD, CAMx_M4 (2-Section) and CAMx N-Section • Discussion of performance metrics • Which ones most appropriate for PM modeling • How to present model performance statistics • Model performance for dummies
Science Options in CAMx4+ • PM Size treatment • M4 2-Section (fine/coarse) all secondary PM is fine • N-Section (CMU treatment) • Aerosol Dynamics • ISORROPIA equilibrium (M4 must use) • MADM dynamic • HYBRID • Aqueous-Phase Chemistry • RADM bulk 1-section (M4 must use) • VSRM (CMU multi-section module)
Effects of Particle Size Distribution • Testing of assumptions of particle size distribution using new merged CAMx4/PMCAMX code (CAMx4+) • M4 = CAMx4 2-Section plus RADM aqueous • EQUI = N-Sections equilibrium + VRSM aqueous • MADM = 10-Sections dynamic + VRSM aqueous • RADM/EQ = 10-Sections equil. + RADM aqueous • RADM/EQ4 = 4-Sections equil. + RADM aqueous • October 17-18, 1995 Southern California Episode
24-Hour Sulfate (g/m3) • October 18, 1995 • M4 peak SO4 39 g/m3 • EQUI peak SO4 51 g/m3 • ~ Long Beach Area • Differences due to more sulfate production in CMU VRSM than RADM aqueous-phase chemistry • Further downwind (Riverside) M4 produces more sulfate than EQUI M4 EQUI
24-Hour Nitrate (g/m3) • October 18, 1995 • M4 peak NO3 83 g/m3 • EQUI peak NO3 54 g/m3 • Observed NO3 peak at Riverside ~40 g/m3 • Differences due to assuming all nitrate is fine vs. PM nitrate represented by 10 size sections (EQUI) M4 EQUI
M4 - EQUI • 24-Hour Nitrate (g/m3) • October 18, 1995 • M4 peak NO3 83 g/m3 • EQUI peak NO3 51 g/m3 • EQUI 10-Section dry deposits NO3 faster due to coarse mode resulting in less NO3 in downwind Riverside area that agrees better with observations • Raises questions regarding CAMx_M4 & CMAQ assumption that all secondary PM is fine M4
1996 Regional PM Modeling of Western US • WRAP Section 309 SIP modeling used 1996 36 km WUSA Database • 1996 MM5 Simulation (Olerud) • 1996 Base Case Emissions (UNC/UCR) • 1996 Base Case Modeling using CMAQ and REMSAD • Old (~2001) version of CMAQ • Many updates to emissions as part of Section 309 modeling • Use 1996 database to evaluate updates • Model updates CMAQ, REMSAD, CAMx • Emission Updates
1996 Regional PM Modeling • Three models to Intercompare and Evaluate • CMAQ Version 4.3 (August 2003) • REMSAD Version 7.06 • CAMx Version 4+ • Develop Processors to Facilitate Intercomparison • CMAQ-to-REMSAD Emissions, IC, and BC Processors • CMAQ-to-CAMx Emissions, IC and BC Processors • Use CMAQ plume rise estimated in 3-D emission files • Substantial reduction in size of emission inputs • 3-D CMAQ files to 2-D plus (i,j,k) data
Notes on Science Summary of PM Models • CMAQ, CAMx_M4 & CAMx_4Sec all used RADM Aqueous-Phase Chemistry • CAMx_4Sec (N-Section) can also use CMU VRSM, but more computationally demanding • All models used equilibrium (ISORROPIA) approach • Dynamic and Hybrid available in CAMx4+ but computationally demanding • All models configured with CB4 Chemistry • REMSAD uses Micro-CB4 • Some changes in rates, especially Nitrate chemistry
Modal vs. Sectional Size Approaches Three Modes: Ten Sections: Although can integrate modal distribution in CMAQ to get PM2.5, in practice usually assume first two modes make up PM 2.5
Old CMAQ/REMSAD SO4 PerformanceSec 309 Old CMAQ = V0301 Early 2001New CMAQ = V4.3 August 2003 + MCIP2.2 October 2003 WRAP MF Meeting Improvements in CMAQ Performance using new version
1996 Revised Evaluation – Western USA • January/July Comparisons w/ 4 Models • CMAQ V4.3 • REMSAD • CAMx_M4 • CAMx_4Sec • (F) = All coarse mode PM in CM • (C) = All Secondary PM is Fine • IMPROVE Network (~50 Sites in WUSA & 1996) • Only PM2.5 is speciated • CAMx-4Sec (F) & (C) comparisons can address secondary PM coarse mode issues
Revised WRAP 1996 CMAQ Modeling 95 x 85 36 km Grids EPA 1996 MM5 Simulation 18 Vertical Layers MCIP2.2, MM5REMSAD and MM5CAMx Processing of MM5 CB4 Chemistry
SO4 IMPROVE – January 1996 CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
SO4 IMPROVE – January 1996 CMAQ Red CMAQ RedCAMx_4Sec (F) CAMx_4Sec (C)
SO4 IMPROVE – July 1996 CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
SO4 IMPROVE – July 1996 CMAQ Red CMAQ RedCAMx_4Sec (F) CAMx_4Sec (C)
SO4 Time Series • Grand Canyon NP • CMAQ & REMSAD OBS = Red 1996 Annual • CMAQ & CAMx_M4 Models Exhibit Similar Behavior, e.g., Miss Observed High SO4 in Mid-June
NO3 IMPROVE – January 1996 CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
NO3 IMPROVE – January 1996 CMAQ Red CMAQ RedCAMx_4Sec (F) CAMx_4Sec (C)
NO3 IMPROVE – July 1996 CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
NO3 IMPROVE – July 1996 CMAQ Red CMAQ RedCAMx_4Sec (F) CAMx_4Sec (C)
NO3 Time Series • Grand Canyon NP • CMAQ & REMSAD OBS = Red 1996 Annual • CMAQ & CAMx_M4 Models Exhibit Similar Behavior, e.g., Underestimate Summer Observed NO3
OC IMPROVE – 1996 Annual CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
EC IMPROVE – 1996 Annual CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
Soil IMPROVE – 1996 Annual CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
CM IMPROVE – 1996 Annual CMAQ Red CMAQ RedREMSAD Blue CAMx_M4 Blue
Presentation of PM Model Performance • Need to evaluate on a PM component basis (total PM mass or extinction doesn’t cut it) • Many networks using different instrumentation and species definitions so should not mix networks • Many statistical measures available that often give conflicting signals, which ones should we stress? • Subregional model performance needed • Interested in low as well as high values • No real PM benchmarks available • Results in tables of of numbers that are difficult to interpret and impossible to read
Presentation of PM Model Performance • Example Summary Model Performance plots for 1996 WUSA PM Model Intercomparison • Plot Bias versus Gross Error (borrowed from TCEQ) • Compare with Each Other and with Performance “Benchmarks” – Example “Benchmarks” used: • 15% Bias and 35% Error (15%/35%) [borrowed from ozone modeling] • 50% Bias and 75% Error (50%/75%) • Not suggesting these be the benchmarks, used for example purposes only
Presentation of PM Model Performance • Mean Normalized Bias Error (MNBE) • Mean Fractional Bias Error (MFBE) • Normalized Mean Bias Error (NMBE) NMBE = Absolute Bias/Average Observed
Organic Carbon (OC) IMPROVE January 1996 July 1996
Elemental Carbon (EC) IMPROVE January 1996 July 1996
Preliminary Conclusions 1996 WUSA Modeling • Although models exhibit variations in model performance, no one model is clearly performing better than the others across all species and periods • Model performance in revised 1996 Base Case simulations much improved over previous runs • Improved MM5 processing (e.g., MCIP2.2) • Improved model formulations (e.g., CMAQ V4.3, CAMx3+, REMSAD V7) • Model performance still less than stellar and varies by species and time period • 1996 MM5 simulation has issues • CAMx_4Sec run without NaCl estimate approximately 10% secondary PM is coarse (e.g., 12% SO4 across the WUSA IMPROVE network)