1. 1 Traffic Restrictions Associated with the Sino-African Summit: Reductions of NO x Detected from Space Yuxuan Wang, Michael B. McElroy, K. Folkert Boersma School of Engineering and Applied Sciences, Harvard University Henk J. Eskes, J. Pepijn Veefkind KNMI, De Bilt, The Netherlands KNMI, De Bilt, The Netherlands TEMIS Workshop, ESRIN, 8 Oct 2007 Forbidden CityDowntown Traffic 6pm

2. 2 Chinese Emissions in the Global Context Van der A et al., 2006 Jan 1996Dec 2004 NO 2 column density Secular Trends of NO 2 over China (TEMIS)

3. 3 Traffic Restrictions in Beijing during the Sino-African Summit: a natural experiment  Sino-African Summit: Nov 4 – 6, 2006  Purpose of traffic restrictions: to accommodate the meeting; dress-rehearsal for the 2008 Olympics Games  Traffic Restrictions major initiatives  Bans on government vehicles (490,000 vehicles kept in garage)  Increased capacity in public transportation  Road restrictions  call on private drivers  Public News: 30% reduction in on-road vehicles (800,000 out of 3 million)

4. 4 Questions Addressed in this Study: 1)Can we see the impact on the atmosphere in the near-real-time fashion? 2) How big was the impact using the “top-down” constraints? Is it consistent with the bottom-up estimate? The immediate, global, monitoring capability of NO 2 made available through www.TEMIS.nl

5. 5 Measuring NO 2 from Space 1995-2001 40 x 320 km 2 footprint global coverage: 3 days GOME 2004-present 13 x 24 km 2 footprint global coverage: 1 day OMI SBUV instruments in low Earth orbit Climatological seasonal variability of NO x sources near-real-time monitoring of local situations

6. 6 Ozone Monitoring Instrument (OMI)  Dutch-Finnish made; aboard NASA EOS Aura satellite   Nadir-viewing instrument measuring direct and atmosphere-backscattered sunlight from 270 – 500 nm (NO 2, SO 2, O 3 )  equator crossing time 0145 and 1345: (Beijing crossing time 1-3pm)   Wide field of view (2600 km)  global coverage in one day  Small pixel sizes (13 x 24 km 2 in the nadir )  Near-real-time monitoring capability made available through www.temis.nl

7. 7 Ozone Monitoring Instrument (OMI)  Dutch-Finnish made; aboard NASA EOS Aura satellite   Nadir-viewing instrument measuring direct and atmosphere-backscattered sunlight from 270 – 500 nm (NO 2, SO 2, O 3 )  equator crossing time 0145 and 1345: (Beijing crossing time 1-3pm)   Wide field of view (2600 km)  global coverage in one day  Small pixel sizes (13 x 24 km 2 in the nadir )  Near-real-time monitoring capability made available through www.temis.nl

8. 8 Day-to-day Variability in OMI NO 2  Apparent decrease in NO 2 over Beijing during the Summit  Some variations not driven by emission changes  Need a chemical transport model to interpret the OMI observations  Need a chemical transport model to interpret the OMI observations. Before Summit during Summit after Summit Oct. 29 Nov. 5Nov. 7

9. 9 The GEOS-Chem Model 1.Global chemical transport model; gas and aerosol chemistry 2.Driven by time-specific, ‘realistic’, assimilated meteorology from NASA GMAO 3.2 o (lat.) x 2.5 o (long.), full representation of the whole troposphere 4.Extensively tested against measurements (aircraft, surface, and satellite) inside and downwind of China [Wang et al., 2004a; 2004b; Wang et al., 2007a] 5.Most recent national emission inventory for China [Streets et al., 2006; Zhang et al., 2007]

10. 10 OMI Observations and Model Comparisons OMI (0.5 o x0.5 o ) OMI (2 o x2.5 o ) model  The model has adequate ability in simulating the variations  The decrease in NO 2 over Beijing during the Summit not captured by the model

11. 11 OMI Observations and Model Comparisons OMI (0.5 o x0.5 o ) model

12. 12 Consistent temporal variations at two scales OMI NO 2 (2 o x2.5 o ) OMI NO 2 (0.5 o x0.5 o ) Model Scale (2 o x2.5 o ) Beijing Urban Area (40km x 40km)

13. 13 Model reproduces spatial patterns NO 2 column NO 2 / NO x ratio NO x emis

14. 14 OMI-Derived Changes in Emissions 40% reduction !

15. 15 Meteorological conditions

16. 16 Summary 1.Successful detection of reductions in NO x from space 2.GEOS-Chem model is able to reproduce day-to- day variations in NO 2 columns (when without dramatic changes in emissions) 3.Vehicular emissions in Beijing  Bottom-up method suggests 70% of total NO x sources  Our results: 40% reduction in total NO x  50% reduction in vehicular sources  50% reduction in vehicular sources  Need to be tested by detailed energy consumption data (i.e., gasoline sales) 4.Traffic restrictions were very effective in reducing emissions of NO x in urban areas of Beijing.

17. 17 The China Project at Harvard University 1.Reliable data on emissions (bottom-up method) 2.A model assimilating meteorological data with a comprehensive treatment of chemistry (GEOS-Chem model and its nested-grid version) 3.High quality data for key species providing a meaningful test of the model (ground station, aircraft, and satellite) http://chinaproject.harvard.edu/ Elements of its Atmospheric Science Program

18. 18 What have we benefited from TEMIS? 1.The Near-Real-Time data from OMI 2.Stratospheric NO 2 columns assimilated from the GOME instrument [Wang et al., 2007a] 3.Easy data access and communication! TEMIS can be made even better… 1.The OMI data format (currently 0.3 GB for one day worth of data) 2.Customized on-line plotting capability (user-defined color scale)

19. 19 Future Directions using TEMIS Products 1.To obtain more quantitative constraints on emissions of NO x 2.The 2008 Summer Olympics and anticipated improvement in air quality 3.Monitoring of SO 2 emissions in China (acid rain and sulfate aerosols) using SCIAMACHY and OMI products. 4.Trans-boundary pollution transport (intra-Asia, Asia – U.S; Europe-Asia)

20. 20 Acknowledgement 1.Financial support from the National Science Foundation, USA 2.Pieternel Levelt and the OMI Science team 3.Helpful discussions with Shuxiao Wang, Weihua Ge and Chen Dan at Tsinghua University and Qiang Zhang at the Argonne National Lab. 4. The TEMIS project and support