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Impact of Temporal Fluctuations in Power Plant Emissions on Air Quality Forecasts

Impact of Temporal Fluctuations in Power Plant Emissions on Air Quality Forecasts. Prakash Doraiswamy 1 , Christian Hogrefe 1,2 , Eric Zalewsky 2 , Winston Hao 2 , Ken Demerjian 1 , J.-Y. Ku 2 and Gopal Sistla 2,* 1 Atmospheric Sciences Research Center, University at Albany, Albany, NY

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Impact of Temporal Fluctuations in Power Plant Emissions on Air Quality Forecasts

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  1. Impact of Temporal Fluctuations in Power Plant Emissions on Air Quality Forecasts Prakash Doraiswamy1, Christian Hogrefe1,2, Eric Zalewsky2, Winston Hao2, Ken Demerjian1, J.-Y. Ku2 and Gopal Sistla2,* 1 Atmospheric Sciences Research Center, University at Albany, Albany, NY 2 New York State Department of Environmental Conservation (NYSDEC), Albany, NY * retired 10/11/2010

  2. Background • Air quality models such as CMAQ are being used to provide air quality forecast guidance. • The accuracy of forecasts from such modeling systems is influenced, in part, by the quality of the emissions used and their associated uncertainties. • The typical emissions processing uses annual emissions estimates for anthropogenic emissions that are then allocated to each hour based on “typical” or “average” temporal profiles for each source category. • Some source categories, such as electric generating units (EGUs), are known to exhibit significant temporal variations in emissions in response to weather conditions.

  3. Goals of this study • Retrospective simulations have the advantage of using actual EGU emissions for the modeling period, while routine air quality forecasting simulations have to rely on the typical EGU profiles. • Hence, this study examines the sensitivity of predicted ozone levels to these differences in EGU emissions • Objectives: • What is the nature and magnitude of the variability introduced into the model predictions of Ozone due to the differences in EGU temporal profiles/emissions? • How widespread is this variability? • How does this variability affect the model performance?

  4. Model simulations • Time period: May to September 2007 (relatively warm summer in the 2005-2009 time frame) • Met model: • NCEP WRF-NMM 12z cycle weather forecast fields for the above time period (from archives maintained by NYSDEC) • CMAQ v4.7.1 model • Emissions: based on OTC 2007 “proxy” inventory • a mix of 2007 MANE-VU inventories for non-road and point sources, EPA-CHIEF 2005 point source inventory for all other regions, and interpolated 2007 emissions for other source-sectors/regions • 2 emission scenarios: “Actual” & “Average”

  5. Emission Scenarios • “Actual” emissions: • Temporal allocation of EGU emissions is based on measured hourly emissions from Continuous Emissions Monitors (CEMs) for EGUs • For MANE-VU states, 2007 unit-level hourly and annual total emission files for EGUs were developed using hourly CEMs data, state-submitted emissions and cross-walk files • For non-MANE-VU states, 2005 annual EGU emissions were temporally allocated by SMOKE using 2007 hourly CEMs files obtained from CAMD and cross-referencing ORIS/boiler ID • “Average” emissions: • Allocates annual emission totals to specific hours using temporal profiles derived from the actual 2007 CEM data on a state-by-state basis

  6. Emissions

  7. MANE-VU Daily EGU NOx Emissions

  8. MANE-VU Average Diurnal EGU NOx Emissions • “Average” emissions appeared to increase rapidly during the early morning hours until about 10 am and then stabilized until about 6 pm and then began to decrease. • “Actual” emissions increased at a slower rate than the average emissions, and reached a maximum peak around 3 pm, a little later than the average profile.

  9. Effect on Ozone Predictions At each grid in the modeling domain Across the ozone monitors in the MANE-VU region

  10. Maximum Effect on Modeled 1-hr and 8-hr Daily Max Ozone • For each emission scenario, calculate 1-hr and 8-hr daily max ozone for each grid • Take the difference of the calculated daily 1-hr and 8-hr daily max between the two emission scenarios (“Actual” – “Average”) • What is the maximum/minimum of this difference at each grid over the entire period from May-Sep 2007? • Represents the extreme effect at each grid unpaired in time • Shown on the next 2 slides

  11. Max/Min daily difference of 1-hr Daily Max from May-Sep 2007 Peak 1-hr Daily Max Min 1-hr Daily Max

  12. Max/Min daily difference of 8-hr Daily Max from May-Sep 2007 Peak 8-hr Daily Max Min 8-hr Daily Max

  13. Total Variability in Hourly Ozone • The difference of the hourly ozone between the two emission scenarios (“Actual” – “Average”) can be both positive and negative • The maximum hourly difference and the minimum hourly difference were determined each day. The difference between the max and min gives the range or the total variability for that day. • What is the maximum of this daily total variability at each grid?

  14. Maximum of the daily total variability from May-Sep 2007

  15. Distribution of Max and Min Difference in 1-hr and 8-hr Daily Max at the monitors in MANE-VU Region • < ±3 ppb difference at 75% of the sites • Certain sites showed effect as much as ±10 ppb

  16. Distribution of Average Difference in 1-hr Daily Maxat the monitors in MANE-VU • 4 time periods: • all days • Obs. O3 > 75 ppb, • “Actual” emissions > 90th percentile in the respective state • “Actual” emissions < 10th %ile • Near zero on average, with 75% of the sites showing < ±0.5 ppb difference • Slightly larger inter-quartile range (IQR) on high O3/electric demand days & narrow IQR on low emission days

  17. Distribution of Average Difference in 8-hr Daily Maxat the monitors in MANE-VU • Similar to the effect on 1-hr daily max, but a slightly narrower distribution in 8-hr daily max than 1-hr daily max for the respective case

  18. Time Series of hourly variability:2 sites with contrasting response • NY Site, urban site with high local emissions density • Mostly negative difference in O3 • PA Site – rural agricultural site • Mostly positive difference in O3

  19. Time Series of daily variability: 1-hr Daily Max O3 NY Site, urban site PA Site – rural agricultural site Ozone changes mostly coincide with emission changes. Higher “Actual” emissions results in negative O3 difference at NY site, while positive O3 difference at PA site.

  20. Time Series of daily variability: 1-hr Daily Max O3 Response dependent on the photochemical regime of the region and its location relative to the source / path of plume NY Site, urban site PA Site – rural agricultural site Ozone changes mostly coincide with emission changes. Higher “Actual” emissions results in negative O3 difference at NY site, while positive O3 difference at PA site.

  21. Comparison with Observations 8-hr daily max: Norm. Mean Bias

  22. Summary • “Actual” emissions were typically greater than “Average” emissions on days leading to an ozone episode. • The impact on Ozone varied by location, and could be positive or negative. • Maximum impact of ±3 ppb and an average impact of < ±0.5 ppb in 1-hr or 8-hr daily max across 75% of the monitors in the MANE-VU region – similar to variability resulting from meteorology or emission inventories • The nature of the impact appears to be dependent upon the photochemical regime of the region and its location relative to the source/path of the plume.

  23. Acknowledgements & Disclaimer • This study was funded in part by NYSDEC and the New York State Energy Research and Development Authority (NYSERDA) under agreement #10599. • The results presented here have not been reviewed by the funding agencies. The views expressed in this paper are those of the authors and do not necessarily reflect the views or policies of NYSDEC or the sponsoring agency.

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