Pressure Gradient Force: Causes and Characteristics

Pressure Gradient Force (PGF) is a fundamental concept in meteorology that drives air movement from high to low pressure areas. The PGF is directed from high to low pressure, perpendicular to isobars, and its strength is determined by the spacing of isobars. This force plays a critical role in shaping weather patterns and influences wind direction and speed. Explore the dynamics of PGF, its mathematical representation, and its relationship with air pressure and density variations with height. Learn about the balance between PGF and gravity in the hydrostatic relationship and the impact of Coriolis Force on wind direction. Gain insights into the complex interactions governing atmospheric motions.

• Pressure Gradient Force
• Meteorology
• Wind Dynamics
• Air Pressure
• Atmospheric Forces

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Uploaded on Feb 17, 2025 | 1 Views

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Presentation Transcript

1. WIND

2. Pressure Gradient Force (PGF) Causes air to move from high pressure toward low pressure Three characteristics of the PGF: 1) directed from H to L 2) perpendicular to isobars 3) magnitude is proportional to isobar spacing (i.e., tight spacing = stronger PGF)

3. Pressure Gradient Force (PGF) Dp Dx PGF=-1 08 r 12 04 density 16 00 horizontal distance H L 12 04 08 1) directed from H to L 2) perpendicular to isobars 3) magnitude is proportional to isobar spacing (i.e., tight spacing = stronger pgf) In this example, isobars are evenly spaced so PGF has the same strength everywhere.

4. Pressure Gradient Force

5. Pressure Gradient Force 4 mb/100 km

6. PGF = Pressure Gradient Force close isobar spacing, strong PGF farther spacing, weak PGF

7. Change of Air Pressure and Density with Height

8. HYDROSTATIC RELATIONSHIP 700 mb 800 mb 900 mb Upward pressure gradient force (PGF) is balanced by gravity (g).

9. HYDROSTATIC RELATIONSHIP Dp Dz=-rg gravity vertical distance Despite very strong vertical pressure gradients, vertical winds (rising and sinking air) are generally weak. The vertical PGF is NOT responsible for vertical winds.

10. Coriolis Force (COR) (viewed from above) turntable target Dart misses target as target has rotated out of position dart gun Time = 1 (now) Time = 2 (15 sec. later)

11. Coriolis Force (COR) (as viewed while riding on turntable) turntable A mysterious force caused the dart to veer to the right of the target Definition: force applied to a body in motion that appears to cause it to turn to its right in the Northern Hemisphere (or to its left in the Southern Hemisphere). target dart gun

12. Coriolis Force Simple Coriolis demonstration: https://www.youtube.com/watch?v=dt_XJp77-mk&app=desktop

13. Coriolis Force (COR) Not a real force arises from our frame of reference as we travel on a planet that is constantly rotating Deflection by COR (right or left) is greater for a) faster rotation, and b) greater distance travelled (higher speed) COR =2WVsinf constants wind speed latitude @ equator, sin 0 = 0, so COR = 0 @ poles, sin 90 = 1, so COR = maximum

14. Coriolis Force: Equatorward-moving Air

15. Coriolis Force: Eastward-moving Air

16. Coriolis Force In the Northern Hemisphere, the Coriolis force causes an air parcel to deflect TO ITS RIGHT (to the right of its direction of motion), regardless of the direction of motion. This deflection increases toward the North Pole.

17. Variation of Coriolis Force with Speed and Latitude Stronger wind speed = stronger Coriolis force

18. Coriolis Force: Poleward-Moving Air

19. REVIEW OF KEY FORCES Pressure gradient force (PGF) High to Low Perpendicular to the isobars Proportional to isobar spacing Coriolis force (COR) Acts to right of parcel direction in N. Hemisphere (and to left in S. Hemisphere) Maximum at poles, zero at equator Proportional to wind speed (Chap. 8, pp. 209 213)

20. EVSC 3300 Atmosphere and Weather (3 credits) EVSC 3301 (1 credit lab. optional for non- majors) Prerequisite: one semester of calculus