1. Lessons 22,23,24 Upper Level Winds

2. Upper wind Upper winds are driven by pressure differences aloft.
Upper level pressure gradients are produced by the horizontal temperature distribution in the upper atmosphere.
These temperature differences aloft are referred to as:
Thermal Gradients, resulting in
Thermal Wind Components.

3. 500 mb Contours

4. Contour Lines

5. Contour Charts Constant Pressure Charts
Contour lines are lines of constant height.
Strength of upper wind is:
inversely proportional to distance between the contour lines.
The closer the distance between the contours the stronger the upper wind

6. Contour Charts Vg = geostrophic wind speed.
 h = change in height of contour lines.
d = distance between contours.

8. Upper Air (Contour) Charts
Isotherms of mean temperature not usually drawn.
Contour charts are drawn for standard pressure levels
700 mb.
500 mb.
400 mb.
300 mb. Etc.

9. Upper Air Charts, cont’d
The strength of the upper wind is directly proportional to the slope of the isobaric surface.
Lines of constant height above the surface are plotted on the charts
These lines are called CONTOURS and are plotted for a predetermined height change.
Upper winds blow along the contours.

10. Upper Air Charts, cont’d
A contour line is also referred to as an ISOHYPSE, i.e. a line of constant height

11. Pressure Changes Aloft
1000 mb msl Pressure

12. Pressure Changes Aloft

13. Pressure Changes Aloft
Thermal Wind Component Directed into board  L H

14. Thermal Wind Component
The thermal wind component:
strength is directly proportional to the magnitude of the Thermal Gradient.
is directed along isotherms of mean temperature.
in the NH the direction is such that the cold air mass is on the left and on the right in the SH.
usually increase in strength with height.

15. Thermal Wind Components
The vector difference between between winds at different levels is dependent on:
the horizontal distribution of MEAN temperature in the layer.

16. Upper Geostrophic Wind
Is the vector sum of the lower geostrophic wind and the thermal wind component for the layer.
Warm Air

17. Average Tropospheric Thermal Wind Component

18. Average Stratospheric Thermal Wind Component

19. 500 mb Contour Chart

21. H

22. General character of Upper Winds
Below the tropopause
Cold air is to the north in N. hemisphere and to S. in southern hemisphere
Therefore thermal wind components are westerly.
Upper winds with height become more westerly increasing up to the tropopause.

23. Upper Winds (cont.) Above the tropopause (stratosphere).
The temperature distribution is reversed.
Warmer air is above the poles and colder is aloft at the equator.
Thermal wind components are easterly.
Upper winds therefore decrease with increasing height and may become easterly at very high altitudes.

24. Global Upper Atmospheric Circulation

25. Upper Wind Flow

26. Average upper winds - January

27. Average upper winds - July