History of Ozone

1. History of Ozone • Discovered in 1840 by Christian Friedrich Schönbein . • In the 1920’s Gordon Dobson made the first O3 column measurements. 1 DU = 1x10-3m thick layer of pure ozone at standard temperature and pressure. • In 1930 Sydney Chapman proposed a mechanism for ozone in the stratosphere.

2. The Stratosphere from: http://okfirst.ocs.ou.edu/train/meteorology/graphics/VertTP.gif

3. Ozone in the Stratosphere • Shields the surface of the Earth from harmful UV radiation. From: http://www.atmosphere.mpg.de/enid/208.html

4. Ozone in the Stratosphere From: Jacob

5. The Chapman Mechanism

6. The Chapman Mechanism From: Jacob

7. The Chapman Mechanism (2) fast (3) (1) slow O2 O O3 (4) slow

8. The Ox Family • Reaction 1: Production of Ox • Reaction 4: Loss of Ox

9. The Chapman Mechanism Assuming steady-state for either O or O3:

10. The Chapman Mechanism Everywhere in the stratosphere

11. O3 in the Stratosphere Derive an expression for the steady-stateof O3 in the stratosphere: Find steady-state for O

12. O3 in the Stratosphere

13. O3 in the Stratosphere From: Jacob

14. Catalytic Ozone Destruction X is a catalyst and may be: X = H, OH, NO, Cl, or Br

15. z T The HOx Family in the Stratosphere • Source: Water vapor • Source: methane, H2 stratosphere cold trap, T≈190K PH2O≈2.5x10-4 torr at 75mbar (3.5ppmv) tropopause troposphere

16. The HOx Family in the Stratosphere

17. Catalytic Ozone Destruction (HOx)

18. Catalytic Ozone Destruction (HOx) Cycle II Cycle I • Cycle I: important at higher z and only during the day • Cycle II: important at lower z and also at night

19. Catalytic Ozone Destruction (HOx) • Termination occurs when: • H2O and HNO3 may mix back to the troposphere and be removed. • However:

20. The NOx Family in the Stratosphere • Source: N2O • Source: Direct emissions of NO to the stratosphere only about 5%

21. Catalytic Ozone Destruction (NOx) Active in the daytime -reaction scheme should look familiar?! Active in the day or night -a little different than cycle II To complete the catalytic cycle in the daytime

22. Null Cycles Ox Ox ‘Null cycles’ do not lead to the formation or destruction of O3. -ties up reactive species (in this case, NOx) reducing their ability to destroy ozone.

23. Catalytic Ozone Destruction • Cycles may be ‘short-circuited’ through competing reactions: Leads to O3 destruction Leads to null cycle

24. Catalytic Ozone Destruction (NOx) • Termination of catalytic cycles occur when: • However:

25. Reservoirs • For NOx: • HNO3, and N2O5 are reservoirs of NOx • NOy = NOx + reservoirs • NOx/NOy gives us an idea of how effective NOx is at destroying ozone. • For HOx: • H2O and HNO3 are reservoirs of HOx • HOy = HOx + reservoirs • HOx/HOy gives us an idea of how effective HOx is at destroying ozone.

26. Mixed Cycles • The HOx and NOx cycles are coupled: An increase of stratospheric HOx causes a decrease in the effectiveness of NOx towards destroying O3.

27. Transport in the Stratosphere From: http://www-as.harvard.edu/people/faculty/djj/book/powerpoints/

28. Global Ozone Distribution From: http:woudc.ec.gc.ca/e/ozone/Curr_allmap_g.htm

29. Global Ozone Distribution From: http:woudc.ec.gc.ca/e/ozone/Curr_allmap_g.htm

30. Tropospheric NOx and HOxversusStratospheric NOx and HOx • In the troposphere (ozone production): • In the stratosphere (ozone destruction): HOx The troposphere has extremely low atomic oxygen concentrations. NOx The stratosphere has high ozone and atomic oxygen concentrations relative to the troposphere. HOx NOx