John M. Bane Sara M. Haines Melanie F. Meaux University of North Carolina Chapel Hill

1. Atmospheric Internal Boundary LayerOver the Oregon Shelf During Summer 2001:Its Causes and Oceanic Consequences John M. Bane Sara M. Haines Melanie F. Meaux University of North Carolina Chapel Hill Roger M. Samelson Oregon State University Corvallis Sponsor: National Science Foundation

2. ATMOSPHERIC SURFACE PRESSURE Height of 1000 mb surface (m) Average: May-August 2001 ALEUTIAN LOW L COAST E. PACIFIC HIGH H THERMAL LOW L

3. ATMOSPHERIC SURFACE PRESSURE Height of 1000 mb surface (m) Average: May-August 2001 Columbia R. .Tillamook .Newport .Florence 160 170

4. Northward Wind Stress Newport NDBC Buoy (N/m2) DOWNWELLING (25%) UPWELLING (75%) May June July August MONTH 2001

5. Northward Wind Stress Newport NDBC Buoy (N/m2) DOWNWELLING (25%) UPWELLING (75%) May June July August MONTH 2001 July 24

6. ATMOSPHERIC SURFACE PRESSURE Height of 1000 mb surface (m) 5pm PDT 24 July 2001 L COAST L H L L

7. AIRCRAFT WINDS (150m) July 24, 2001 20 m/sec Latitude Longitude

8. AIRCRAFT WINDS (150m) July 24, 2001 20 m/sec VERTICAL SECTIONS Latitude Longitude

9. q Atmos q Ocean T July 24 Line 4

10. Temperature Inversion q Mixed Layer Atmos q Ocean T July 24 Line 4

11. Temperature Inversion q Mixed Layer COOL Atmos q Ocean T July 24 Line 4

12. OFFSHORE SHELFBREAK q NEARSHORE COOL Atmos q Ocean T July 24 Line 4

13. ATMOSPHERIC POTENTIAL TEMPERATURE PROFILES July 24 Line 4 Altitude (m) SHELFBREAK OFFSHORE SHELFBREAK NEARSHORE NEARSHORE Atmos q COOL OFFSHORE q (K)

14. ATMOSPHERIC POTENTIAL TEMPERATURE PROFILES July 24 Line 4 Near-surface dT/dz => sensible heat flux into cool, upwelled waters Flux ~10 W/m2 Altitude (m) SHELFBREAK OFFSHORE SHELFBREAK NEARSHORE NEARSHORE Atmos q COOL OFFSHORE q (K)

15. ATMOSPHERIC POTENTIAL TEMPERATURE PROFILES July 24 Line 4 Altitude (m) OFFSHORE SHELFBREAK TOP OF IBL NEARSHORE Atmos q COOL IBL q (K)

16. q COOL Atmos q IBL Ocean T July 24 Line 4

17. q m/sec Atmos q, v Atmos q Ocean T July 24 Line 4

18. q m/sec LOW SPEED Atmos q, v Atmos q IBL Ocean T July 24 Line 4

19. q m/sec LOW SPEED Atmos q, v Atmos q AIRCRAFT TRACK Ocean T July 24 Line 4

20. qv Wind v u speed IBL

21. qv Wind Ri v u speed INV IBL IBL

22. SEA SURFACE TEMP and BUOY WINDS

23. INTERNAL BOUNDARYLAYER HEIGHT (meters)

24. h (IBL thickness, m) h = 18 X1/2 [Hsu, 1983] X (downwind distance, km) Internal Boundary Layer Thickness vs. Downwind Distance July 24, 2001

25. h (IBL thickness, m) h = 18 X1/2 [Hsu, 1983] X (downwind distance, km) Internal Boundary Layer Thickness vs. Downwind Distance July 24, 2001

26. SEA SURFACE TEMP and BUOY WINDS SLOWER WINDS NEARSHORE => + WIND STRESS CURL

27. ty z . . . . x UPWELLING WITH CONSTANT SOUTHWARD WIND STRESS (No IBL)

28. ty z . IBL . . . x UPWELLING WITH VARIABLE SOUTHWARD WIND STRESS (IBL Present)

29. EKMAN PUMPING (m/day) NORTHERLY WINDS SOUTHERLY WINDS NORTHWARD WIND (NDBC Buoy, m/sec)

30. Conclusions • Synoptic atmospheric pressure field determines first-order • wind stress spatial and temporal patterns • Wind stress can be modified by local effects • Atmosphere-to-ocean sensible heat flux lowers surface • air temperature over cool, upwelled waters • An Internal Boundary Layer forms, and increased static • stability plus thermal wind effect in the IBL lowers • the nearshore wind stress • IBL positive wind stress curl => upward Ekman pumping • of about 1 m/day

31. August 01, 2001Remnant upwelled waterunder moderate southerly winds

32. ATMOSPHERIC SURFACE PRESSURE Height of 1000 mb surface (m) 5pm PDT 01 August 2001 L L L COAST H L

33. ATMOSPHERIC SURFACE PRESSURE Height of 1000 mb surface (m) 5pm PDT 01 August 2001 L L L COAST H L

34. AIRCRAFT WINDS (150m) August 01, 2001 20 m/sec Latitude Longitude

35. AIRCRAFT WINDS (150m) August 01, 2001 20 m/sec VERTICAL SECTIONS Latitude Longitude

36. Atmos q Ocean T Aug 01 Line 6

37. ATMOSPHERIC POTENTIAL TEMPERATURE PROFILES August 01 Line 6 Altitude (m) SHELFBREAK NEARSHORE Atmos q OFFSHORE q (K)

38. ATMOSPHERIC POTENTIAL TEMPERATURE PROFILES August 01 Line 6 Altitude (m) TOP OF IBL IBL Atmos q COOL q (K)

39. q COOL Atmos q IBL Ocean T Aug 01 Line 6

40. q Atmos q IBL Ocean T Aug 01 Line 6

41. Conclusions • Synoptic atmospheric pressure field determines first-order • wind stress spatial and temporal patterns

42. Conclusions • Synoptic atmospheric pressure field determines first-order • wind stress spatial and temporal patterns • Wind stress can be modified by local effects

43. Conclusions • Synoptic atmospheric pressure field determines first-order • wind stress spatial and temporal patterns • Wind stress can be modified by local effects • Atmosphere-to-ocean sensible heat flux lowers surface • air temperature over cool, upwelled waters

44. Conclusions • Synoptic atmospheric pressure field determines first-order • wind stress spatial and temporal patterns • Wind stress can be modified by local effects • Atmosphere-to-ocean sensible heat flux lowers surface • air temperature over cool, upwelled waters • An Internal Boundary Layer forms, and increased static • stability in the IBL lowers the nearshore wind stress

45. Conclusions • Synoptic atmospheric pressure field determines first-order • wind stress spatial and temporal patterns • Wind stress can be modified by local effects • Atmosphere-to-ocean sensible heat flux lowers surface • air temperature over cool, upwelled waters • An Internal Boundary Layer forms, and increased static • stability in the IBL lowers the nearshore wind stress • IBL positive wind stress curl => upward Ekman pumping • of about 0.1-0.5 m/day

46. q m/sec JET JET LOW SPEED Atmos q, v Atmos q Ocean T July 24 Line 4

47. q COOL Atmos q Ocean T July 24 Line 4

48. q Atmos q IBL Ocean T Aug 01 Line 6