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Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development.

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Presentation on theme: "Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development."— Presentation transcript:

1 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Golam Sarwar, Jia Xing, James Godowitch, Donna Schwede, Rohit Mathur Atmospheric Modeling and Analysis Division National Exposure Research Laborotary U.S. Environmental Protection Agency 2013 ITM Miami, Florida, USA August 26-30, 2013 Impact of RACM2, halogen chemistry, and updated ozone deposition velocity on hemispheric ozone predictions

2 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Overview of CB05TU and RACM2 Carbon Bond mechanism has been widely used in air quality models – CMAQ currently uses Carbon Bond 2005 with updated toluene chemistry (CB05TU) – References: Yarwood et al., 2005 and Whitten et al., 2010 Regional Atmospheric Chemistry Mechanism (RACM2) is a new mechanism – Specifically developed for regional applications – Reference: Goliff et al., 2013 Examine the impact of these mechanisms on ozone over northern hemisphere – Motivations: – We use hemispheric predictions for generating BC for continental US – Previous studies showed CB05 predicts high ozone over water which affects model predictions in continental US domain (Mathur et al., 2010 and 2012)

3 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Halogen chemistry over gulfs and oceans Recent studies suggest halogen chemistry can destroy ozone over water Bromine/iodine chemistry are important; details are emerging Current CMAQ model does not contain these halogen reactions Read et al. (2008) and Mahajan et al. (2010) measured O 3 in the Cape Verde archipelago in Atlantic Ocean – They suggested halogens can destroy ozone by 1.8-2.0 ppbv/day – We developed an effective ozone loss reaction using data from Read et al. (2008) with a first order loss of 2.0x10 -6 s -1 for the reaction – We employed it in CMAQ to account for the halogen mediated O 3 loss over the over gulfs and oceans only during day and within PBL – Read et al., Nature, 453, 1232-1235, 2008 and Mahajan et al., Atmospheric Chemistry & Physics, 2010

4 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Ozone deposition velocity over water Helmig et al. (2012) measured ozone V d over gulfs and oceans – They reported median values of 0.009-0.27 cm s -1 to different water bodies – Ref: Helmig et al., JGR, 117, D04305, 2012 We analyzed current CMAQ-estimated ozone V d over gulfs and oceans – CMAQ V d values are an order of magnitude lower than observed values – We revised ozone V d treatment in CMAQ following Chang et al. (2004) – It enhanced ozone V d similar to the observed values over water – Ref: Chang et al., Atmospheric Environment, 38, 1053–1059, 2004

5 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory CMAQ estimated O 3 deposition velocity Ozone dep velocity with revised treatment (daily average) Ozone dep velocity with existing treatment Ozone dep velocity with revised treatment

6 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Modeling details Community Multiscale Air Quality (CMAQv50) hemispheric model –WRF-CMAQ coupled model –Modeling domain: northern hemisphere –Horizontal grid size: 108-km –Vertical resolution: 44 layers from surface to 50 kpa Model-ready emissions were developed using –Emissions Database for Global Atmospheric Research (EDGAR) Simulation period –Three months: June, July, August, 2006 –Spin-up period: One-month (May, 2006 )

7 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Modeling details Three different model simulations were performed – CB05TU – RACM2 – RACM2 + halogen reaction + enhanced O 3 deposition velocity Compare model predictions with observations from several field campaigns – Texas Air Quality Study 2006 – INTEX Ozonesonde Network Study (IONS-06) – Southern Hemisphere ADditional OZonsondes (SHADOZ)

8 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Comparison of CB05TU & RACM2 ozone predictions at surface RACM2 enhances ozone in polluted areas while decreasing it in remote areas. Increases occur due to greater NO x recyling and more active organic chemistry in RACM2. Decreases in remote areas occur due to the lower organic nitrate in RACM2.

9 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Effect of halogen reaction + enhanced deposition velocity on ozone predictions The halogen reaction and enhanced deposition velocity decrease O 3 predictions over water. Most of the decreases occur due to the halogen reaction.

10 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Observations sites for model comparison Sable Island Hilo, Hawaii Trinidad Head Gulf of Mexico

11 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Comparison with observed data at Sable Island & Gulf of Mexico RACM2 over-predicts ozone compared to observations near surface Mixed performances aloft The halogen reaction and enhanced ozone V d improve the comparison Sable Island, NS Gulf of Mexico

12 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Comparison with observations at Trinidad Head & Hilo, Hawaii At Trinidad Head, both over-predict near surface but RACM2 is better ~1000-3000-m In the pacific Oceans at Hilo, RACM2 predictions compare better The halogen reaction and enhanced ozone V d improve the comparison Trinidad Head Hilo, Hawaii

13 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Summary  Incorporated RACM2 into the hemispheric CMAQ model  RACM2 enhances O 3 in polluted areas while decreasing in remote areas –RACM2 over-predicts surface O 3 compared to observed data in polluted areas –RACM2 improves aloft O 3 predictions in some cases in polluted areas –RACM2 predictions compare better with observed data in remote areas (Hilo)  Incorporated an effective halogen reaction and updated O 3 V d in CMAQ –They reduce O 3 predictions over water bodies –The majority of the reduction occurs due to the halogen reaction –Model O 3 predictions with these treatments compare better with observed data  Future plans –Generate boundary conditions for continental US using these results –Perform simulations with these boundary conditions for continental US

14 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Extra slides

15 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Overview of CB05TU and RACM2 CB05TURACM2 Year updated/developed2005, 20102013 Number of reactions172363 Number of photolytic reactions2433 Number of chemical species80134

16 Office of Research and Development National Exposure Research Laboratory, Atmospheric Modeling and Analysis Division Office of Research and Development National Exposure Research Laboratory Example reaction in CB05TU and RACM2 (reaction of ethane) CB05TURACM2 C2H6 + HO = 0.991*ACD + HO2 + 0.991*XO2 + 0.009*XO2N C2H6 + HO = C2H5OO C2H5OO + NO = HO2 + NO2 + ACD C2H5OO + HO2 = OP2 C2H5OO + MO2 = HO2 + 0.75*HCHO + 0.75*ACD + 0.25*MOH + 0.25*EOH C2H5OO + ACO3 = 0.5*HO2 + 0.5*MO2 + ACD + 0.5*ORA2 C2H5OO + NO3 = HO2 + NO2 + ACD ACD=acetaldehyde, OP2=organic peroxide, ORA2=acetic acid, NO=nitric oxide, NO2=nitrogen dioxide, HO2=hydroperoxy radical, ETHP=peroxy radical, MO2=methyl peroxy radical, HCHO=formaldehyde, MOH=methanol, EOH=ethanol, ACO3=acetyl peroxy radical, NO3= nitrate radical, XO2= NO to NO2 conversion, XO2N= NO to RNO2 conversion


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