Biogenic Emissions of Organics: Global Budgets and Implications IGAC Conference, Annecy, France September 11, 2008 Colette L. Heald Russ Monson, Mick Wilkinson,

Slides:



Advertisements
Similar presentations
Simulating isoprene oxidation in GFDL AM3 model Jingqiu Mao (NOAA GFDL), Larry Horowitz (GFDL), Vaishali Naik (GFDL), Meiyun Lin (GFDL), Arlene Fiore (Columbia.
Advertisements

Dylan Millet Harvard University with
Global Constraints on Biogenic Particles Goldschmidt Conference August 19, 2011 Colette L. Heald Photo courtesy: Cam McNaughton (taken from NASA’s DC-8)
QUESTIONS 1.Using the EKMA diagram (the ozone isopleth discussed at the end of last class), find what ozone levels would result if emissions of NO x were.
QUESTIONS 1.Is hexane more or less reactive with OH than propane? 2.Is pentene or isoprene more reactive with OH?
Predicted change in global secondary organic aerosol concentrations in response to future climate, emissions, and land-use change Colette L. Heald NOAA.
Update on: 1. Secondary Organic Aerosol 2. Biogenic VOC emissions Colette L. Heald Chemistry Climate Working Group Meeting February.
Predicted change in global SOA in response to future climate, emissions, and land-use change Colette L. Heald NOAA Climate and Global Change Postdoctoral.
Organic Carbon Aerosol: An Overview (and Insight from Recent Field Campaigns) Colette L. Heald NOAA Climate and Global Change Postdoctoral Fellow
Organic Aerosol: From Oxidation to Optical Depth IGAC Conference, Halifax, Canada July 14, 2010 Colette L. Heald Acknowledgements: Jesse Kroll (MIT), Jose.
Primary Biological Aerosol Particles: an important part of the global organic aerosol budget? GEOS-Chem User’s Meeting April 7, 2009 Colette L. Heald and.
Organic Particulate Matter: New constraints from satellite and field observations Reed College October 28, 2010 Colette L. Heald
Organic Carbon in the Troposphere NOAA Seminar June 11, 2008 Colette L. Heald* *With acknowledgements to many people at the.
Organic Carbon in the Troposphere: Mysteries and Challenges Michigan Tech October 19, 2009 Colette L. Heald * * with acknowledgements to many people at.
Organic Carbon during AMAZE-08: Preliminary model analysis AMAZE Science Team Meeting, Boulder July 24, 2008 Colette L. Heald
Investigating the Sources of Organic Carbon Aerosol in the Atmosphere Colette L. Heald NOAA Climate and Global Change Postdoctoral Fellow University of.
Organic Carbon Aerosol Colette L. Heald University of California, Berkeley NOAA Summer Institute, Steamboat Springs, CO July 12, 2006.
UP IN THE AIR * : Connecting plants, particles and pollution Colette L. Heald Colorado State University MIT March 11, 2011 * Title taken from George Clooney.
Organic Carbon in the Troposphere: How much is there and can we predict the future? NCAR Seminar May 19, 2008 Colette L. Heald*
REFERENCES Maria Val Martin 1 C. L. Heald 1, J.-F. Lamarque 2, S. Tilmes 2 and L. Emmons 2 1 Colorado State University 2 NCAR.
Dylan Millet, Daniel Jacob, and May Fu Harvard University Thomas Kurosu and Kelly Chance Harvard-Smithsonian Astrophysical Observatory Alex Guenther NCAR.
Using satellite observations to investigate natural aerosol loading Colette L. Heald David A. Ridley, Kateryna Lapina EGU April 5, 2011.
Organic Aerosol: Making complicated particles seem simple 20 th Anniversary Celebration: NOAA Climate and Global Change Postdoctoral Program April 14,
Global BVOC Emission Inventories:
Evaluating the Impact of the Atmospheric “ Chemical Pump ” on CO 2 Inverse Analyses P. Suntharalingam GEOS-CHEM Meeting, April 4-6, 2005 Acknowledgements.
Natural aerosols: Global budgets and climate implications Aerodyne, Inc. April 10, 2009 Colette L. Heald.
MODELING ORGANIC AEROSOL: Where are we going wrong? Colette L. Heald Telluride Workshop on Organic Aerosol August 4, 2008.
Constraining global isoprene emissions with GOME formaldehyde column measurements Changsub Shim, Yuhang Wang, Yunsoo Choi Georgia Institute of Technology.
Evaluating the Role of the CO 2 Source from CO Oxidation P. Suntharalingam Harvard University TRANSCOM Meeting, Tsukuba June 14-18, 2004 Collaborators.
Havala Olson Taylor Pye April 11, 2007 Seinfeld Group Department of Chemical Engineering California Institute of Technology The Effect of Climate Change.
Global Linkages Between Vegetation, Atmospheric Composition and Climate Fall AGU Meeting, San Francisco December 19, 2008 Colette L. Heald Acknowledgements:
SOA vs POA in the Amazon: Current model estimates and predicted change Colette L. Heald Aerosols in the Amazon Workshop February.
Sensitivity of U.S. Surface Ozone to Isoprene Emissions & Chemistry: An Application of the 1°x1 ° North American Nested GEOS-CHEM Model GEOS-CHEM Model.
Development, evaluation, and application of GEOS-Chem driven by CCSM3 meteorological fields Presenter: Daeok (Daniel) Youn Atmospheric Chemistry Modeling.
BIOGENIC VOCs. TOPICS FOR TODAY 1.Why do we care about BVOCs? How are they climate- relevant? 2.What are BVOCs? Why are they emitted? 3.How do we measure.
Emissions of Volatile Organic Compounds by Plants Carbon Metabolism and Atmospheric Chemistry Kolby Jardine Amazon-PIRE Field Course June 2010.
Modeling Elemental Composition of Organic Aerosol: Exploiting Laboratory and Ambient Measurement and the Implications of the Gap Between Them Qi Chen*
Climate and Air Quality: Investigating the Impacts of Changing Landscapes Earth and Atmospheric Sciences Seminar, Cornell University April 10, 2013 Colette.
Estimates of global biogenic isoprene emissions from the terrestrial biosphere with varying levels of CO 2 David J. Wilton 1,2*, Kirsti Ashworth 2, Juliette.
Biogenic Emissions Modeling: MEGAN Christine Wiedinmyer, Tiffany Duhl, Ulzi Vanchindorj, Alex Guenther National Center for Atmospheric Research Tanarit.
Urban Air Pollution Public and Environmental Health Concerns –Elevated levels of toxic compounds Regional and Global Impacts –Background Chemistry and.
Mapping isoprene emissions from space Dylan Millet with
Effect of CO 2 Inhibition of Isoprene Emission Air quality under changes in climate, vegetation and land use Amos P. K. Tai (With Loretta Mickley,
Interannual variability in biogenic emissions driven by dynamic vegetation conditions Daniel Cohan (PI), Adetutu Aghedo, Erin Chavez-Figueroa, and Ben.
. s Yuqiang Zhang 1, J. Jason West 1, Meridith M. Fry 1, Raquel A. Silva 1, Steven J. Smith 2, Vaishali Naik 4, Zachariah Adelman 1, Susan C. Anenberg.
Source vs. Sink Contributions to Atmospheric Methane Trends:
Assessment of the Impacts of Global Change on Regional U.S. Air Quality: A synthesis of climate change impacts on ground-level ozone An Interim Report.
Regulated large-scale annual shutdown of Amazonian isoprene emissions? New insight provided by satellite observations of formaldehyde (HCHO) and of vegetation.
QUESTIONS 1.Is hexane more or less reactive with OH than propane? 2.Is pentene or isoprene more reactive with OH? 3.Using the EKMA diagram (the ozone isopleth.
OVERVIEW OF ATMOSPHERIC PROCESSES: Daniel J. Jacob Ozone and particulate matter (PM) with a global change perspective.
Simulating the Oxygen Content of Organic Aerosol in a Global Model
1 UIUC ATMOS 397G Biogeochemical Cycles and Global Change Lecture 14: Methane and CO Don Wuebbles Department of Atmospheric Sciences University of Illinois,
Dylan Millet Harvard University with D. Jacob (Harvard), D. Blake (UCI), T. Custer and J. Williams (MPI), J. de Gouw, C. Warneke, and J. Holloway (NOAA),
Climatic implications of changes in O 3 Loretta J. Mickley, Daniel J. Jacob Harvard University David Rind Goddard Institute for Space Studies How well.
Peak 8-hr Ozone Model Performance when using Biogenic VOC estimated by MEGAN and BIOME (BEIS) Kirk Baker Lake Michigan Air Directors Consortium October.
MAPPING ISOPRENE EMISSIONS FROM SPACE USING OMI FORMALDEHYDE MEASUREMENTS Dylan B. Millet, Daniel J. Jacob, K. Folkert Boersma, Justin P. Parrella Atmospheric.
Review: Constraining global isoprene emissions with GOME formaldehyde column measurements Shim et al. Luz Teresa Padró Wei-Chun Hsieh Zhijun Zhao.
Organic aerosol composition and aging in the atmosphere: How to fit laboratory experiments, field data, and modeling together American Chemical Society.
Recent and predicted changes in atmospheric composition over the United States from climate, emissions and bark beetles Fall AGU Meeting December 6, 2012.
Land Use Change Impacts on Aerosols International Aerosol Modeling Algorithms Meeting December 10, 2015 Colette L. Heald Jeff Geddes, Sam Silva, Ashley.
Sensitivity of Biogenic Emissions to Climate Jihee Song Global Physical Climatology December 5, 2006.
Observational Constraints on Global Organic Aerosol Telluride Science Research Center Workshop on Organic Aerosol July 30, 2014 Colette L. Heald Xuan Wang,
The Double Dividend of Methane Control Arlene M. Fiore IIASA, Laxenburg, Austria January 28, 2003 ANIMALS 90 LANDFILLS 50 GAS 60 COAL 40 RICE 85 TERMITES.
Terrestrial emissions of isoprene Paul Palmer Division of Engineering and Applied Sciences, Harvard University
Uncertainties in isoprene-NO x -O 3 chemistry: Implications for surface ozone over the eastern United States TEMP PAR Leaf Area ISOPRENE + NO x  O 3 Arlene.
Global Simulation of Secondary Organic Carbon Aerosols Hong Liao California Institute of Technology GEOS-CHEM meeting, April 2005.
Why care about methane Daniel J. Jacob. Global present-day budget of atmospheric methane Wetlands: 160 Fires: 20 Livestock: 110 Rice: 40 Oil/Gas: 70 Coal:
up until since Jan 2008 PhD NOAA postdoc Asst. Professor
Top-down constraints on emissions of biogenic trace gases from North America Dylan Millet with D.J. Jacob, R.C. Hudman, S. Turquety, C. Holmes (Harvard)
Shiliang Wu1 Loretta J. Mickley1, Daniel J
Presentation transcript:

Biogenic Emissions of Organics: Global Budgets and Implications IGAC Conference, Annecy, France September 11, 2008 Colette L. Heald Russ Monson, Mick Wilkinson, Clement Alo, Guiling Wang, Alex Guenther Scot Martin, Qi Chen, Jose Jimenez, Delphine Farmer

ISOPRENE: CONTROLLING AIR QUALITY AND CLIMATE C 5 H 8 : Reactive hydrocarbon emitted from plants (primarily broadleaf trees) Annual global emissions ~ equivalent to methane emissions + OH O3O3 Depletes OH = ↑ CH 4 lifetime IPCC, 2007 Beijing CLIMATE AIR QUALITY

METEOROLOGICAL AND PHENOLOGICAL VARIABLES CONTROLLING ISOPRENE EMISSION LIGHT  Diffuse and direct radiation  Instantaneous and accumulated (24 hrs and 10 days) TEMPERATURE (Leaf-level)  instantaneous and accumulated (24 hrs, 10 days) T PAR LL TT [Guenther et al., 2006] SOIL MOISTURE  suppressed under drought AMOUNT OF VEGETATION  Leaf area index (LAI) Month LAI SUMMER LEAF AGE  Max emission = mature  Zero emission = new

ISOPRENE IN THE FUTURE Isoprene emissions projected to increase substantially due to warmer climate and increasing vegetation density.  LARGE impact on oxidant chemistry and climate  NPP ↑ Temperature↑ Surface O 3 ↑ ppb [Sanderson et al., 2003] Methane lifetime increases [Shindell et al., 2007] SOA burden ↑ > 20% [Heald et al., 2008]

A MISSING FACTOR: ISOPRENE EMISSION INHIBITION BY CO 2 Long-Term growth environment: gene adaptation Dependent on ambient CO 2 Short-term exposure: changes in metabolite pools and enzyme activity Dependent on intercellular CO 2 Empirical parameterization from plant studies [Wilkinson et al., GCB, accepted] To what degree does this CO 2 inhibition counteract predicted increases in isoprene (due to T and NPP)?

2100 (A1B): CO 2 INHIBITION COMPENSATES FOR TEMPERATURE INCREASE See that ↑in T activity factor ~ compensated by ↓ in CO 2 activity factor 696 TgC/yr Isoprene emissions in 2100 Decrease when CO 2 inhibition included  31% Dotted=2000 Solid=2100 Global Model: NCAR CAM3-CLM3 (2  x2.5  )

CONCLUSION: ISOPRENE EMISSIONS PREDICTED TO REMAIN ~CONSTANT Important implications for oxidative environment of the troposphere… * With fixed vegetation E isop (TgCyr -1 ) (A1B) MEGAN MEGAN with CO 2 inhibition

UNLESS…CO 2 FERTILIZATION IS STRONG CLM DGVM projects a 3x increase in LAI associated with NPP and a northward expansion of vegetation. [Alo and Wang, 2008]  Isoprene emissions more than double! (1242 TgCyr -1 ) BUT, recent work suggests that NPP increases may be overestimated by 74% when neglecting the role of nutrient limitation [Thornton et al., 2007] [Heald et al., GCB, accepted]

PRIMARY BIOLOGICAL AEROSOL PARTICLES (PBAP) POLLEN BACTERIA VIRUSES FUNGUS ALGAE PLANT DEBRIS How much does this source contribute to sub-micron OC? Jaenicke [2005] suggests may be as large a source as dust/sea salt (1000s Tg/yr) Elbert et al. [2007] suggest emission of fungal spores ~ 50 Tg/yr LARGE particles (> 10 µm)

PRELIMINARY EMPIRICAL PBAP SIMULATION Based on Elbert et al. [2007] who summarize observed PBAP concentrations and estimate 50 Tg/yr of fungal spores emitted over entire size range. Global Annual Mean Burden POASOAPBAP fine PBAP int < 1  m 1-3  m Tg Global Model: GEOS-Chem (2  x2.5  ) Surface: June ??

ANY INDICATION OF PBAP IN AMAZE-08? **PRELIMINARY AMS obs: Scot Martin, Qi Chen (Harvard). Jose Jimenez, Delphine Farmer (CU Boulder) SIMULATED OC Early Feb: Fire influence Field site: close to Manaus, Brazil (in Amazonia), Feb-Mar No obvious indication of an important sub-micron PBAP in the “pristine” Amazon… What about “intermediate” size range?? NEED: (1) better understanding of emission drivers (2) More observations of PBAP

ACKNOWLEDGEMENTS Mick Wilkinson, Russ Monson Clement Alo, Guiling Wang Alex Guenther Qi Chen, Scot Martin Delphine Farmer, Jose Jimenez Andi Andreae