Atmosphere

1. Atmosphere Part III Circulation

2. Content • Importance of Air Movement • Forces control atmospheric motion • Microscale Movement • Mesoscale Movement • Macroscale Movement • Global Pressure Patterns and Planetary Wind System • Synoptic Scale Movement • Climatic Classification and Climatic Regions

3. Importance of Air Movement • Air motion: • Horizontal movement (wind): air movement parallel to the surface. • Vertical movement: sinking and rising masses of air perpendicular to the surface and usually 100-1000 times slower than horizontal movement

4. Horizontal Movement • It is an very important climatic factor. • Wind relocates warm and cold bodies of air.

5. Horizontal Movement • Wind transport water vapour and giving precipitation • Air in rapid motion is a severe environmental hazard. Eg. Typhoon.

6. Vertical Movement • It strongly influence whether the climate and weather will be cloudy and rainy or clear and dry.

7. Air motion and global energy budget • Between about 40oN and 40oS, the amount of incoming radiation exceeds that lost by the cooling of the earth-atmosphere system. • Heat energy must be moved fromsurplus areas to the deficit areas . • Global system of wind circulationplays this vital role.

8. Forces control atmospheric motion • Pressure-gradient force • Coriolis force • Centripetal force • Friction

9. Pressure- Gradient Force • Pressure can be considered as resulting from the weight of air. • Isobars are lines joining points that have same air pressure. • The change in barometer pressure across a horizontal surface or vertical dimension constitute a pressure gradient. • Air move from high to low pressure location. • The magnitude of the force is directly proportional to the steepness of the gradient. • Larger pressure gradient, the faster wind speed.

10. Pressure- Gradient Force • Pressure gradient exists both vertically and horizontally. • Pressure decreases vertically. • Pattern of air pressure close to the surface is reversedin the upper atmosphere. • Warm air expands and rises, so that vertical pressure gradient is less steep. Therefore, above areas of warm air, the pressure tends to be relatively high.

11. Pressure- Gradient ForceHorizontal

12. Pressure- Gradient ForceVertical

13. Coriolis Force • It is a deflecting force which is produced by earth rotation. The force tends to turn the flow of air. • Direction • Northern hemisphere: turn right • Southern hemisphere: turn left • The degree of the deflecting force depend on: • Wind speed • Latitude • Near equator, it has also no effect. • Higher latitudes, it has marked effect • It is the greatest at the poles.

14. Coriolis Force

15. Coriolis Force • Geostrophic wind: • It is the balance effect with the pressure gradient force and the coriolis force.

16. Coriolis Force • Geostrophic Wind

17. Centripetal Force • It applies when the isobaric pattern is markedly curved. • When air is following a curved path, a force is acting centripetally, pulling the air inwards • The balance with these three forces (pressure gradient force, coriolis force and centripetal force) is known as the gradient wind. Low pressure centre High pressure centre

18. Centripetal Force • Gradient winds Low pressure centre High pressure centre

19. Frictional Force • In the lower parts of atmosphere, the frictional drag exerted by the ground on the air flow, which acts as a force pulling against the direction of flow. • Frictionlessens the wind speed, so weakens the coriolis force, and the pressure gradient force asserts its greater strength and cause the air to flow more towards low pressure area.

20. Frictional Force Lower Level Upper Level

21. Scales of air movement

22. Microscale Movement • Above the friction layer: • Air movement is controlled by pressure-gradient force and Coriolis force. (Geostrophic Wind)

23. Microscale Movement • Within the friction layer: • Friction can reduce wind speed and so the effect of Coriolis force will also be reduced. • Pressure-gradient force becomes the dominant. • The angle at which the wind will cross the isobars will vary according to how much frictional reduction of speed takes place.

24. Mesoscale Movement • Land and Sea Breeze Day time

25. Mesoscale Movement • Land and sea breeze Night Time

26. Mesoscale Movement

27. Mesoscale Movement • Katabatic Wind / Mountain Wind Farmers should try to avoid valley-floor location for frost-sensitive crops and plantthem just above the level of frost pocket.

28. Mesoscale Movement • Anabatic wind / Valley wind

29. Mesoscale Movement • Mountain and valley winds

30. Macroscale Movement • Pattern of atmospheric circulation

31. Macroscale Movement • Pattern of atmospheric circulation

32. Macroscale Movement • Upper Westerlies • The existence and intensity of the upper westerly flow is determined by the equator to pole temperature gradient. • This system of westerlies is blowing in a complete circuit about the earth from about 25o almost to the poles.

33. Macroscale Movement • Upper air waves and the jet stream • The uniform flow of the upper-air westerlies are frequently disturbed by the formation of large undulations, called upper air waves / Rossby waves. • The waves develop in a zone of contact between cold, polar air and warm, tropical air. • Jet streams are also a product of the temperature gradient between the equator and the poles. • It concentrated into a few narrow zones where cold and warm air masses come into contact. (Polar front) • It will be best developed during winter for the greatest equator-pole temperature gradient.

34. Jet Stream

35. Rossby Waves

36. Importance of Heat Transfer • In the equatorial seas. • Vast energy is used for evaporation so that the sensible heat transfer to the atmosphere is small., • In equatorial trough • Air rises and cools, the water vapour condenses and release latent heat. The increased height of the air also represents an increased potential energy. • The equatorial air then diverges and flows polewards, so the potential energy is exported to higher latitudes.

37. Importance of Heat Transfer • About 30oN or 30oS (tropical deserts) • The air subsides with adiabatic warming process, the potential energy is converted to sensible heat, and produce clear cloudless skies. • Most incoming energy is used for heating ground surface which then heats the atmosphere. (sensible heat) • During night, energy loss rapidly by radiation, so net surplus of radiation is also small. • In 60oN and 60oS • There is no general cellular circulation, but instead a complicated pattern. • Within these storms warm air masses rise, releasing latent heat and gaining potential energy. • All these transfer of energy through the atmosphere are highly variable, and major differences in the intensity and character of transfer occur over time.

39. Global Pressure Patterns • Standard atmospheric pressure • 1013 hPa • Seven pressure belts • Doldrums: • In the equatorial zone is a belt of low pressure (equatorial trough) – Inter tropical convergence zone (ITCZ) • Subtropical High pressure belts • Lying to the 30oN or 30oS (horse latitudes), air subsiding zone. • Temperate low pressure belts / sub-polar low p.b. • Locate on 60oN and 60oS, meeting place of polar air mass and warm air mass from 30oN or 30oS. • It is also called polar front • Polar high pressure belts. • Locate on North and South Poles. • The pressure belts shift seasonally through several degree of latitude.

40. Pressure Belts and Planetary Winds systems Polar High Sub-polar Low Sub-tropical High Doldrum Sub-tropical High Sub-polar Low Polar High

41. Planetary Wind Systems

43. Planetary Wind Systems • Doldrums: • Between 5oN and 5oS, variable winds and calms. There are no prevailing surface winds here. • Trade wind belts: • Between Doldrums and sub-tropical high pressure belts in both hemisphere. • N. Hemisphere: North-east trade winds • S. Hemisphere: South-east trade winds • The system of doldrums and tradesshifts several degrees of latitudes seasonally north and south. • Westerlies belts • Between latitudes 35o and 60o in both hemisphere. • In southern hemisphere, it is an unbroken of ocean. • ‘the roaring forties’, ‘furious fifties’, ‘screaming sixties’ • Polar easterlies • Locate on both polar zones.

44. Monsoon Winds in Asia • Summer Monsoon • In summer, southern Asia, warm, humid ocean air moves northward and northwestward from Pacific Ocean into Asia. • It is accompanied by heavy rainfall in southeast Asia. • Winter monsoon • In winter, Asia is dominated by a strong centre of high pressure, air blows southward and southeastward toward the equatorial oceans. • It brings dry, clear and cool weather for a period of several months.

45. Monsoon in Asia

46. Synoptic Scale Movement • Air Masses and Fronts • Disturbances in the Mid-Latitude Circulation (Temperate Cyclones) • Disturbances in the Low-Latitude Circulation (Typhoons)

47. Air masses and fronts • Air Masses • A body of air in which the physical properties (temperature, specific humidity) are fairly uniform over a large area is known as an air mass. • The properties of an air mass are derived in part from the regions located. • Two categories of generalized source regions: • Latitudes: thermal properties • Underlying surface: moisture content

48. Air mass Latitudinal Position Underlying surface

49. Air mass • Combination of latitudinal position and underlying surface. • 6 important air masses results

50. Air mass