Climatology Lecture 5

1. ClimatologyLecture 5 ‘Vertical Motion in the Atmosphere’ …Continued... Michael Palmer Room 119, Atmospheric Physics mpalmer@atm.ox.ac.uk

2. Dry Example: Absolute Stability Surface Temp = 34 oC Stable Air No convection No Rain Environ Temp Parcel Temp Temperature

3. Dry Example: Absolute Stability Surface Temp = 34 oC Stable Air No convection No Rain Environ Temp Parcel Temp Temperature

4. Moist Example: Absolute Instability Surface Temp = 34 oC Unstable Air Convection Rain Condensation Level Parcel Temp Temperature Environ Temp

5. Wet Example: Conditional Instability Unstable Air Convection Rain Level of free convection Condensation Level Temperature

6. Vertical Motion • Potential Instability • Absolute Stability Topographically forced stable cloud Pollution dispersion climatology

7. Potential Instability • Conditional instability involves convective ascent of parcels of air • Potential instability involves large scale ascent of layers of air • Instability is potential since the air is stable until lifted by an appropriate amount • Potential Instability may occur if a layer of air is very moist at the bottom but very dry aloft

8. Stability depends on ELR Temperature Environ Temp Parcel Temp

9. Stability depends on ELR Temperature Environ Temp Parcel Temp

10. Z Temperature

11. B’ New ELR A’ Z B Old ELR A Temperature

12. Z B A Temperature

13. A’ Z A Temperature

14. B’ A’ Z B A Temperature

15. B’ Z A’ B A Temperature

16. B’ More unstable A’ Z B Stable A Temperature

17. Potential Instability • The initial lapse rate in the layer AB is stable • On lifting of the entire layer, the base reaches condensation quickly, since it is moist - the slower rate of cooling (SALR) is applicable - but the top of the layer cools at the DALR • The new layer A’B’ is unstable for rising parcels.

18. Vertical Motion • Potential Instability • Absolute Stability Topographically forced stable cloudPollution dispersion climatology

19. Absolute Stability ??

20. Absolute Stability

21. Absolute Stability

22. Environmental lapse rate Z Dry adiabatic lapse rate Temperature

23. Environmental lapse rate 1 Z Dry adiabatic lapse rate Temperature

24. Environmental lapse rate 1 Z 2 Dry adiabatic lapse rate Temperature

25. Environmental lapse rate 1 3 Z 2 Dry adiabatic lapse rate Temperature

26. Environmental lapse rate 1 3 4 Z 2 Dry adiabatic lapse rate Temperature

27. Environmental lapse rate 1 3 5 4 Z 2 Dry adiabatic lapse rate Temperature

28. Absolute Stability 1 3 4 2

29. Absolute Stability

30. Absolute Stability Air hotter and drier on leeward side

35. H E I G H T TEMPERATURE

36. H E I G H T Subsidence Inversion TEMPERATURE

37. H E I G H T Subsidence Inversion Surface Radiation Inversion TEMPERATURE

38. H E I G H T Early Morning TEMPERATURE

39. H E I G H T Daytime Early Morning TEMPERATURE

43. (Unstable) (Near neutral stability) Γ (dashed) – DALR Solid - ELR

49. Stack Height • Statistical characteristics of surface and non-surface inversion layers: depth, strength, frequency • longer stacks: increased eddy diffusion • effective stack height: H = hs + dh hs= physical height of stack dh = f (Stability, wind speed,stack exit velocity, stack diameter, temperature of emission, emission rate)