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The Atmosphere: Oxidizing Medium In Global Biogeochemical Cycles EARTH SURFACE Emission Reduced gas Oxidized gas/ aerosol Oxidation Uptake Reduction.

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Presentation on theme: "The Atmosphere: Oxidizing Medium In Global Biogeochemical Cycles EARTH SURFACE Emission Reduced gas Oxidized gas/ aerosol Oxidation Uptake Reduction."— Presentation transcript:

1 The Atmosphere: Oxidizing Medium In Global Biogeochemical Cycles EARTH SURFACE Emission Reduced gas Oxidized gas/ aerosol Oxidation Uptake Reduction

2 Only A Narrow UV Window (300-320 nm) for O( 1 D) Production 30 o equinox midday Solar spectrum

3 O( 1 D) production in the troposphere?

4 OH Radical: Main Tropospheric Oxidant O 3 + hv  O 2 + O( 1 D) (1) O( 1 D) + M  O + M (2) O( 1 D) + H 2 O  2OH (3) Primary source: Sink: oxidation of reduced species CO + OH  CO 2 + H CH 4 + OH  CH 3 + H 2 O HCFC + OH  H 2 O + … Major OH sinks globally GLOBAL MEAN [OH] = 1.0x10 6 molecules cm -3

5 QUESTIONS 1. How would a thinning of the stratospheric ozone layer affect the source of OH in the troposphere? 2. How might global warming affect the source of OH in the troposphere?

6 Global Sources of Methane Natural Sources Anthropogenic Sources

7 Global Distribution of Methane NOAA/CMDL surface air measurements

8 Historical Trends In Methane Historical methane trend Recent methane trend

9 RECENT TREND IN METHANE

10 Global Sources of CO

11 Satellite Measurements of Lower Tropospheric CO

12 Satellite Measurements of Upper Tropospheric CO

13 Global Distribution of CO NOAA/CMDL surface air measurements

14 O3O3 O 3 + hv  OH + OH H2OH2O Stratosphere COCH 4 1-2 x10 13 moles yr -1 2-4 x10 13 moles yr -1 6-10 x10 13 moles yr -1 3 x10 13 moles yr -1 OH only from strat O 3 would be titrated X Troposphere How are tropospheric OH levels maintained?

15 Climatology of observed ozone at 400 hPa in July from ozonesondes and MOZAIC aircraft (circles) and corresponding GEOS- CHEM model results for 1997 (contours). GEOS-CHEM tropospheric ozone columns for July 1997. GLOBAL DISTRIBUTION OF TROPOSPHERIC OZONE Li et al. [2001]

16 NO x EMISSIONS (Tg N yr -1 ) TO TROPOSPHERE FOSSIL FUEL 23.1 AIRCRAFT 0.5 BIOFUEL 2.2 BIOMASS BURNING 5.2 SOILS 5.1 LIGHTNING 5.8 STRATOSPHERE 0.2

17 MAPPING OF TROPOSPHERIC NO 2 FROM THE GOME SATELLITE INSTRUMENT (July 1996) Martin et al. [2002]

18 LIGHTNING FLASHES SEEN FROM SPACE (2000) DJF JJA

19 PEROXYACETYLNITRATE (PAN) AS RESERVOIR FOR LONG-RANGE TRANSPORT OF NO x

20 NO x, HNO 3, AND PAN OVER THE TROPICAL PACIFIC Aircraft observations from PEM-Tropics B, March-April 1999 Staudt et al. [2003]

21 QUESTIONS 1. The prospect of hydrogen-fueled cars is leading to study of the effect of increasing atmospheric H 2. Would you expect H 2 to be oxidized by OH? What would be the effect on the oxidizing power of the atmosphere? 2. Loss of NO x in the troposphere takes place by NO 2 +OH, same as in the stratosphere. What is the effect of this reaction on tropospheric ozone?

22 QUESTION 1. How does the lifetime of NO x respond to a change in the NO x concentration? If NO x emissions were to double, would NO x concentrations more than double or less than double?

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