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Winds Atmospheric Circulation Ch22.3 p561 Wind is horizontal air movement.

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Presentation on theme: "Winds Atmospheric Circulation Ch22.3 p561 Wind is horizontal air movement."— Presentation transcript:

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2 Winds Atmospheric Circulation Ch22.3 p561 Wind is horizontal air movement

3 Three causes of motion 1. Convection 2. Pressure Differences 3. Coriolis Effect

4 Convection Currents Warm air rises and cool air sinks because of density  This is called a convection current

5 Winds are caused by the uneven heating of Earth’s surface.uneven heating  Land heats up and cools off quicker than water  So the large amount of water on Earth moderates our temperatures

6 2. Pressure Differences pressure differences in the atmosphere that are a result of temperature differences WIND ALWAYS FLOWS FROM HIGH TO LOW PRESSURE

7 Winds blow from high to low pressure

8 3. Coriolis EffectCoriolis Effect The deflection of objects to the right in the northern hemisphere— called the Coriolis Effect  Due to rotation of the earth

9  effect greatest at poles, decrease to zero at equator

10 Coriolis Effect

11 Global Circulation Patterns  Global winds are the result of several cell-like circulation patterns brought about by  uneven heating of Earth’s surface  and compounded by effects of the Earth’s rotation.

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13 Doldrums or ITCZ  At the equator hot air rises and forms an area known as the doldrums  At the boundary between the troposphere and stratosphere it spreads out to the N or S ITCZ—Intercontinental convergence zone

14 Horse latitudes  As it reaches about 30 N and S of the equator it cools and descends  Sinking air causes an area of dry weather  The sinking air also causes an area with weak winds  This caused problems for ships

15 Trade Winds  Winds flowing south from the horse latitudes is deflected to the west in the northern hemisphere  These aided trading by ship

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17 Jet Stream  Jet streams are fast flowing, relatively narrow air currents found in the atmosphere at around 11 kilometers (36,000 ft) above the surface of the Earth, just under the tropopause.currentsatmosphereEarth tropopause  They form at the boundaries of adjacent air masses with significant differences in temperature, such as of the polar region and the warmer air to the south. temperaturepolar region

18 Current jet stream data

19 Highs and Lows?  Winds circle Clockwise and out around a high  Highs generally mean cold dry air that is sinking  High pressure usually = fair weather

20 Low Pressure Systems  Winds circle counterclockwise and into a low  Warmer air rises and cools and forms clouds and precipitation  Low pressure usually = rainy weather

21 Explore  Draw an H in the middle of your paper Draw a 1 inch circle lightly around the H.  Place all five fingers inside the circle using your left-hand if right handed and your right if left-handed.  Standing up if necessary, turn your hand slowly clockwise and gradually spread your fingers and thumb our as your hand turns. Don’t move the map. You hand will end up flat on the paper.

22  Bring your fingers back inside the circle.  Number the starting position of each finger and thumb with your thumb as number 1, index finger 2, and so on.  Slowly rotate your hand clockwise and gradually spread out your fingers and thumb, stopping after about one inch of motion. Number the position of each finger again.  Continue spreading and numbering every inch or so, until your hand is completely flat on the paper.  Connect each number in a smooth arch, Place arrows at the end of each arch. The result should be a spiral pattern, typical of a high pressure system.

23 Explore Low  Draw an L in the middle of your paper Draw a 1 inch circle lightly around the L.  Place your non-writing hand, palm down on the circle. Rotate your hand counterclockwise, bring your thumb and fingers up into the circle. Practice this twisting motion without moving the paper.  Place your palm down again, and number the position of each finger and thumb, with the thumb as one.

24  Slowly rotate counterclockwise and gradually bring in your fingers and thumb, numbering the position of the position of each finger after about one inch of motion  Connect each number in a smooth arch, ending with an arrow pointed toward the L. This pattern is typical of a low pressure system.

25 Wind always blows f rom high to low

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27 Local Wind Patterns  Monsoons  Land breeze/Sea breeze  Chinook

28 Monsoon In winter, air flow is from cooler (H pressure) to warmer (L pressure) ocean  Air from the land is dry  Dry season In summer, air flow is reversed  Air flows from the cooler ocean to the hotter (L pressure) land  Wet season

29 Sea Breeze  During the day land heats faster than the water. The hot less dense air rises and cooler air from the sea rushes in to take its place.

30 Land breeze Since the air over land cools more rapidly than the air over water, a temperature difference is established, with cooler air present over land and relatively warmer air located over water.

31 Chinook  A wind on the eastern side of the Rockies formed when air descends and is compressed and warms Effects:  Rapid. Large Temperature Changes Can Occur  Snow may melt or evaporate through sublimation  Loss of moisture due to significant drops in humidity

32 Beaufort scale  Used to estimate wind speeds  Originally used by sailors

33 Beaufort Scale on Water

34 Beaufort Scale on Land

35 Wind Energy

36 Wind and Pressure Relationship Lab

37 Remember Topographic Maps?

38 Contours are imaginary lines that join points of equal elevation on the surface of the land Now we will use these with equal temperature and pressure

39 Same Concept—Different Use  Isotherm =equ al temperature  Isobar =equal barometric pressure Isobar

40 contour interval (CI) 1. The contour intervals vary 2. Isobars often have an interval of 4 3. Read the directions or look at examples to see the contour level

41 Tips for understanding contour lines.  There are a few rules that topographic contours must obey, however, and once you understand these rules the map becomes an extremely useful and easy to use tool.

42  As a result of this every contour line must eventually close on itself to form an irregular circle  Contour lines on the edge of a map do not appear to close on themselves because they run into the edge of the map, but if you got the adjacent map you would find that, eventually, the contour will close on itself. 1) Every point on a contour line represents the exact same temperature or pressure

43 2) Contour lines can never cross one another.  Each line represents a separate temperature or pressure and you can’t have two different temps or pressures at the same point.

44 3)Points shown are reporting stations  There may be areas that do not report or have no station

45 4) The closer contour lines are to one another, the higher the wind speed. 

46 Where is the wind speed high? Where is it low?

47 5) Inside a series of closed contours (the contours make a circle) is a High or Low pressure

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