Abstract Using OMI ozone profiles as the boundary conditions for CMAQ calculations significantly improves the agreement of the model with ozonesonde observations.

Slides:

Advertisements

Similar presentations

Variability in Ozone Profiles at TexAQS within the Context of an US Ozone Climatology Mohammed Ayoub 1, Mike Newchurch 1 2, Brian Vasel 3 Bryan Johnson.

Advertisements

Interpreting MLS Observations of the Variabilities of Tropical Upper Tropospheric O 3 and CO Chenxia Cai, Qinbin Li, Nathaniel Livesey and Jonathan Jiang.

Data assimilation of trace gases in a regional chemical transport model: the impact on model forecasts E. Emili 1, O. Pannekoucke 1,2, E. Jaumouillé 2,

Impact of Seasonal Variation of Long-Range Transport on the Middle Eastern O 3 Maximum Jane Liu, Dylan B. Jones, Mark Parrington, Jay Kar University of.

Integrating satellite observations for assessing air quality over North America with GEOS-Chem Mark Parrington, Dylan Jones University of Toronto

Comparisons of TES v002 Nadir Ozone with GEOS-Chem by Ray Nassar & Jennifer Logan Thanks to: Lin Zhang, Inna Megretskaia, Bob Yantosca, Phillipe LeSager,

THE IMPACTS OF TRANS-BOUNDARY TRANSPORT OF AEROSOLS ON THE REGIONAL AIR QUALITY: A case study of Mexican wildland fire on May 1998 Hee-Jin In 1, Daewon.

On average TES exhibits a small positive bias in the middle and lower troposphere of less than 15% and a larger negative bias of up to 30% in the upper.

1 Surface nitrogen dioxide concentrations inferred from Ozone Monitoring Instrument (OMI) rd GEOS-Chem USERS ` MEETING, Harvard University.

Influence of the Brewer-Dobson Circulation on the Middle/Upper Tropospheric O 3 Abstract Lower Stratosphere Observations Models

2 nd GEO-CAPE Community Workshop Boulder, CO May 11-13, 2011 Spatio-temporal Variability of Ozone Laminae Michael J. Newchurch 1, Guanyu Huang 1, John.

Ability of GEO-CAPE to Detect Lightning NOx and Resulting Upper Tropospheric Ozone Enhancement Conclusions When NO emissions from lightning were included.

Tropospheric Ozone Laminar Structures and Vertical Correlation Lengths Michael J. Newchurch 1, Guanyu Huang 1, Brad Pierce 3, John Burris 2, Shi Kuang.

Introduction A new methodology is developed for integrating complementary ground-based data sources to provide consistent ozone vertical distribution time.

Intercomparison methods for satellite sensors: application to tropospheric ozone and CO measurements from Aura Daniel J. Jacob, Lin Zhang, Monika Kopacz.

Template Improving Sources of Stratospheric Ozone and NOy and Evaluating Upper Level Transport in CAMx Chris Emery, Sue Kemball-Cook, Jaegun Jung, Jeremiah.

Impact of Emissions on Intercontinental Long-Range Transport Joshua Fu, Yun-Fat Lam and Yang Gao, University of Tennessee, USA Rokjin Park, Seoul National.

Chemical and Aerosol Data Assimilation Activities during CalNex R. Bradley Pierce NOAA/NESDIS/STAR Allen Lenzen 1, Todd Schaack 1, Tom Ryerson 2, John.

1 Satellite data assimilation for air quality forecast 10/10/2006.

Estimating the Influence of Lightning on Upper Tropospheric Ozone Using NLDN Lightning Data Lihua Wang/UAH Mike Newchurch/UAH Arastoo Biazar/UAH William.

TOP-DOWN CONSTRAINTS ON REGIONAL CARBON FLUXES USING CO 2 :CO CORRELATIONS FROM AIRCRAFT DATA P. Suntharalingam, D. J. Jacob, Q. Li, P. Palmer, J. A. Logan,

1 Using Hemispheric-CMAQ to Provide Initial and Boundary Conditions for Regional Modeling Joshua S. Fu 1, Xinyi Dong 1, Kan Huang 1, and Carey Jang 2 1.

Assimilating tropospheric ozone data from TES Mark Parrington, Dylan Jones University of Toronto Kevin Bowman Jet Propulsion Laboratory California Institute.

TRENDS IN ATMOSPHERIC OZONE FROM A LONG-TERM OZONE CLIMATOLOGY Jane Liu 1,2, D. W. Tarasick 3, V. E. Fioletov 3, C. McLinden 3, J. H. Y. Jung 1, T. Zhao.

EOS Aura Science Team Meeting, October, 2008, Columbia, MD AURA OMI Ozone Profiles for Large-scale CMAQ Boundary Conditions with Lightning Effects.

Tropospheric ozone variations revealed by high resolution lidar M. J. Newchurch 1, John Burris 2, Shi Kuang 1, Guanyu Huang 1, Wesley Cantrell 1, Lihua.

Melanie Follette-Cook Christopher Loughner (ESSIC, UMD) Kenneth Pickering (NASA GSFC) CMAS Conference October 27-29, 2014.

Ozone Lidar Observations for Air Quality Studies Lihua Wang 1, Mike Newchurch 1, Shi Kuang 1, John F. Burris 2, Guanyu Huang 3, Arastoo Pour-Biazar 1,

Planetary Boundary-layer Ozone Flux using Ozone DIAL and Compact Wind Aerosol Lidar (CWAL) in Huntsville AL Guanyu Huang 1, Michael J. Newchurch 1, Shi.

Michael J. Newchurch 1*, Shi Kuang 1, Lihua Wang 1, Kevin Knupp 1, Thierry Leblanc 2, Raul J. Alvarez II 3, Andrew O. Langford 3, Christoph J. Senff 3,4,

Methods for Incorporating Lightning NO x Emissions in CMAQ Ken Pickering – NASA GSFC, Greenbelt, MD Dale Allen – University of Maryland, College Park,

Itsushi UNO*, Youjiang HE, Research Institute for Applied Mechanics, Kyushu University, Kasuga, Fukuoka, JAPAN Toshimasa OHARA, Jun-ichi KUROKAWA, Hiroshi.

C. Hogrefe 1,2, W. Hao 2, E.E. Zalewsky 2, J.-Y. Ku 2, B. Lynn 3, C. Rosenzweig 4, M. Schultz 5, S. Rast 6, M. Newchurch 7, L. Wang 7, P.L. Kinney 8, and.

National Aeronautics and Space Administration Jet Propulsion Laboratory California Institute of Technology Tropospheric Emission Spectrometer Studying.

Template Reducing Vertical Transport Over Complex Terrain in Photochemical Grid Models Chris Emery, Ed Tai, Ralph Morris, Greg Yarwood ENVIRON International.

GEOS-CHEM Modeling for Boundary Conditions and Natural Background James W. Boylan Georgia Department of Natural Resources - VISTAS National RPO Modeling.

Model evolution of a START08 observed tropospheric intrusion Dalon Stone, Kenneth Bowman, Cameron Homeyer - Texas A&M Laura Pan, Simone Tilmes, Doug Kinnison.

Status of the Development of a Tropospheric Ozone Product from OMI Measurements Jack Fishman 1, Jerald R. Ziemke 2,3, Sushil Chandra 2,3, Amy E. Wozniak.

Institute of Atmospheric Physic

Estimating background ozone in surface air over the United States with global 3-D models of tropospheric chemistry Description, Evaluation, and Results.

Improved understanding of global tropospheric ozone integrating recent model developments Lu Hu With Daniel Jacob, Xiong Liu, Patrick.

1 Monitoring Tropospheric Ozone from Ozone Monitoring Instrument (OMI) Xiong Liu 1,2,3, Pawan K. Bhartia 3, Kelly Chance 2, Thomas P. Kurosu 2, Robert.

Estimating PM 2.5 from MODIS and MISR AOD Aaron van Donkelaar and Randall Martin March 2009.

Simulation Experiments for TEMPO Air Quality Objectives Peter Zoogman, Daniel Jacob, Kelly Chance, Xiong Liu, Arlene Fiore, Meiyun Lin, Katie Travis, Annmarie.

Critical Assessment of TOMS-derived Tropospheric Ozone: Comparisons with Other Measurements and Model Evaluation of Controlling Processes M. Newchurch.

H. Worden Jet Propulsion Laboratory, California Institute of Technology J. LoganHarvard University TES ozone profiles compared to ozonesondes ABSTRACT:

Critical Assessment of TOMS-derived Tropospheric Ozone: Comparisons with Other Measurements and Model Evaluation of Controlling Processes M. Newchurch.

1 RAQMS-CMAQ Atmospheric Chemistry Model Data for the TexAQS-II Period : Focus on BCs impacts on air quality simulations Daewon Byun 1, Daegyun Lee 1,

Influence of Lightning-produced NOx on upper tropospheric ozone Using TES/O3&CO, OMI/NO2&HCHO in CMAQ modeling study M. J. Newchurch 1, A. P. Biazar.

TES and Surface Measurements for Air Quality Brad Pierce 1, Jay Al-Saadi 2, Jim Szykman 3, Todd Schaack 4, Kevin Bowman 5, P.K. Bhartia 6, Anne Thompson.

What is the Uncertainty Caused by IC/BCs in the Regional/Urban Ozone Simulations? Linking CMAQ with GEOS-CHEM Global/Regional/Urban Multiscale Study Nan-Kyoung.

Convective Transport of Carbon Monoxide: An intercomparison of remote sensing observations and cloud-modeling simulations 1. Introduction The pollution.

Satellite Remote Sensing of the Air Quality Health Index Randall Martin, Dalhousie and Harvard-Smithsonian Aaron van Donkelaar, Lok Lamsal, Dalhousie University.

Chapter 6: Present day ozone distribution and trends relevant to climate change A. Gaudel, O. R. Cooper, G. Ancellet, J. Cuesta, G. Dufour, F. Ebojie,

LNOx Influence on Upper Tropospheric Ozone Lihua Wang 1, Mike Newchurch 1, Arastoo Biazar 1, Williams Koshak 2, Xiong Liu 3 1 Univ. of Alabama in Huntsville,

M. Newchurch 1, A. Biazar 1, M. Khan 2, B. Koshak 3, U. Nair 1, K. Fuller 1, L. Wang 1, Y. Park 1, R. Williams 1, S. Christopher 1, J. Kim 4, X. Liu 5,6,

Analysis of Satellite Observations to Estimate Production of Nitrogen Oxides from Lightning Randall Martin Bastien Sauvage Ian Folkins Chris Sioris Chris.

Xiaomeng Jin and Arlene Fiore

Application of OMI Ozone Profiles in CMAQ

Spatio-temporal Variability 2nd GEO-CAPE Community Workshop

LNOx Influence on Upper Tropospheric Ozone Mike Newchurch1, Lihua Wang1, Arastoo Biazar1, Williams Koshak2, Xiong Liu3 1Univ. of Alabama in Huntsville,

1st TEMPO Applications Workshop

Randall Martin Dalhousie University

Evaluation of the MERRA-2 Assimilated Ozone Product

Intercomparison of tropospheric ozone measurements from TES and OMI –

Diurnal Variation of Nitrogen Dioxide

Satellite data assimilation for air quality forecast

Intercomparison of tropospheric ozone measurements from TES and OMI

2019 TEMPO Science Team Meeting

Presentation transcript:

Abstract Using OMI ozone profiles as the boundary conditions for CMAQ calculations significantly improves the agreement of the model with ozonesonde observations during IONS06. This improvement results from both representing the free- tropospheric ozone amounts more accurately and also from representing recirculating air masses more accurately. A simultaneous assessment of the OMI ozone profiles directly with the sondes indicates agreement to better than 10% throughout the free troposphere with 10-20% differences in the PBL. Abstract Using OMI ozone profiles as the boundary conditions for CMAQ calculations significantly improves the agreement of the model with ozonesonde observations during IONS06. This improvement results from both representing the free- tropospheric ozone amounts more accurately and also from representing recirculating air masses more accurately. A simultaneous assessment of the OMI ozone profiles directly with the sondes indicates agreement to better than 10% throughout the free troposphere with 10-20% differences in the PBL. Fig. 1 OMI O 3 retrievals between mb during Aug. 21, 2006, are gridded to CMAQ horizontal domain. Ozone Monitoring Instrument (OMI) onboard NASA’s AURA satellite provides mapping of O 3 profiles at a nominal ground footprint of 13x48 km 2 at nadir. OMI O 3 profiles during each day are gridded to CMAQ domain (36km x 36km resolution) using a “drop-in-the- box” method. Interpolate gridded OMI O 3 profiles (24 layers) onto 39 sigma layers of CMAQ. Application of OMI Ozone Profiles in CMAQ Conclusions Using OMI ozone profiles as lateral BCs for CMAQ, improves the middle and upper-tropospheric ozone calculations. By modifying modeled O 3 with OMI O 3 throughout model domain once a model-day, further improvement can be made, especially in interior region. OMI/O 3 Data Processing Experiment Description In this study, 4 CMAQ runs are made: (1) cntrl: uses static profiles as the lateral boundary conditions; (2) raqms_bc: obtains lateral boundary conditions from global chemical model output (RAQMS); (3) sat_bc: uses OMI/O 3 as lateral boundary conditions; (4) sat_icbc: uses OMI/O 3 as lateral boundary conditions, and once a model-day, modifies simulated O 3 with OMI O 3. Fig. 2 IONS06 Ozonesonde network. ( ov/intexb/ions06.html). ov/intexb/ions06.html Evaluation with IONS06 ozonesondes IONS06 provides the best set of free tropospheric ozone measurements ever gathered across the continent in a single season data. Of the IONS06 ozonesondes, 252 are chosen for evaluation of CMAQ results. Criteria include: Within CMAQ domain; Launched during UTC1500 ~ 2300, Aug Model Evaluations 212 mb (level 33; ~11584 m) 853 mb (level 15; ~867 m) 501 mb (level 24; ~5352 m) cntrl raqms_bc sat_bc sat_icbc Fig 5. Differences calculated between model simulated O 3 (ppbv) and ozonesondes, as well as between level-2 OMI/O 3 profiles and ozonesondes, during August Fig 4. CMAQ simulated ozone variations at Huntsville, AL, during August Ozonesonde measurements are re-sampled onto CMAQ vertical resolution and over- plotted. Fig 3. O 3 (ppbv) 1900 UTC, 8/21/2006 simulated by 4 CMAQ runs; over plotted with 9 ozonesondes found within 1500~2300 UTC. Using OMI boundary (bc) or bc+initial conditions, results in significantly better agreement between CMAQ and the sondes in the middle and upper troposphere (Figure 3). The temporal evolution seen at Huntsville is also significantly improved throughout the troposphere by using OMI ic/bc information (Figure 4). The monthly mean difference over 252 sonde stations likewise shows the vertical profile of the improvement in CMAQ with increasing amounts of OMI ozone information, including the direct comparison of OMI ozone profiles and ozonesondes in CMAQ space (Figure 5). cntrl raqms_bc sat_bc sat_icbc Contact info: Lihua (Lucy) Wang The 4th GEOS-Chem Users’ meeting at Harvard University in Cambridge, Massachusetts, April 7-10, Mean of (x-sonde)/sonde (%) Sample size = 252 (varies with altitude) Sample size too small (0~50) L. Wang 1, M. Newchurch 1, A. Biazar 1, M. Khan 2, X. Liu 3,4, D. Byun 5, B. Pierce 6 1 UAH, 2 USRA, 3 SAO, 4 NASA/UMBC-GEST, 5 UH, 6 UW