Local and Regional Wind Systems: Understanding Air Pressure and Wind Patterns

1. Chapter19 Air Pressure and Wind

2. Local Winds 19.3 Regional Wind Systems  The local winds are caused either by topographic effects or by variations in surface composition—land and water—in the immediate area.  Land and Sea Breezes • In coastal areas during the warm summer months, the land surface is heated more intensely during the daylight hours than an adjacent body of water is heated. As a result, the air above the land surface heats, expands, and rises, creating an area of lower pressure. At night the reverse takes place.

3. Sea and Land Breezes

4. Sea and Land Breezes, a local phenomenon

5. Local Winds 19.3 Regional Wind Systems  Valley and Mountain Breezes • In mountainous regions during daylight hours, the air along the slopes of the mountains is heated more intensely than the air at the same elevation over the valley floor. Because this warmer air on the mountain slopes is less dense, it glides up along the slope and generates a valley breeze. After sunset the pattern may reverse.

6. Valley and Mountain Breezes

7. How Wind Is Measured 19.3 Regional Wind Systems  Wind Direction • The prevailing wind is the wind that blows more often from one direction than from any other. • In the United States, the westerlies consistently move weather from west to east across the continent.

8. How Wind Is Measured 19.3 Regional Wind Systems  Wind Speed • An anemometer is an instrument that resembles a cup and is commonly used to measure wind speed.

9. Devices to measure Wind

10. El Niño and La Niña 19.3 Regional Wind Systems  El Niño • El Niño is the name given to the periodic warming of the ocean that occurs in the central and eastern Pacific. • At irregular intervals of three to seven years, these warm countercurrents become unusually strong and replace normally cold offshore waters with warm equatorial waters. • A major El Niño episode can cause extreme weather in many parts of the world.

11. Normal Conditions

12. El Niño Conditions

13. El Niño, as a oceanic phenomenon along the coasts of northern Peru and Ecuador, has been documented since the 1500s. Originally, the term El Niño was used to describe the annual appearance of warm waters along the coast of northern Peru around Christmastime. In some years the warm waters appeared earlier and lasted longer. Eventually, the term El Niño was applied to the periods of anomalous warming. The stronger events disrupted local fish and bird populations. History of El Niño

14. Beginning in the late 1800s scientists began to describe large-scale pressure fluctuations. Sir Gilbert Walker and colleagues extended the early studies and determined that a global-scale pressure fluctuation (the Southern Oscillation) is related to rainfall anomalies in many areas of the Tropics (e.g., India and South America). The SO was used as the basis for seasonal rainfall predictions (ca 1930s). History of the Southern Oscillation

15. Naturally occurring phenomenon Equatorial Pacific fluctuates between warmer-than-average (El Niño ) and colder-than-average (La Niña) conditions The changes in SSTs affect the distribution of tropical rainfall and atmospheric circulation features (Southern Oscillation) Changes in intensity and position of jet streams and storm activity occur at higher latitudes The ENSO Cycle

16. Signals in Tropical Pacific: Sea surface temperatures (SSTs) Precipitation Sea Level Pressure The Southern Oscillation (High vs. Low Phases) Low-level Winds and Thermocline Depth El Niño/ Low Southern Oscillation PhaseVS.La Niña/ High Southern Oscillation Phase

17. Sea Surface Temperatures Equatorial cold tongue is stronger than average during La Niña, resulting in negative SST anomalies Equatorial cold tongue is weaker than average or absent during El Niño, resulting in positive SST anomalies

18. Precipitation Enhanced rainfall occurs over warmer-than-average waters during El Niño. Reduced rainfall occurs over colder-than-average waters during La Niña.

19. Sea Level Pressure El Niño: Positive SLP anomalies over the western tropical Pacific, Indonesia and Australia. Negative SLP anomalies over eastern tropical Pacific, middle and high latitudes of the North Pacific, and over U.S. Opposite pattern for La Niña. The pressure see-saw between the eastern and western tropical Pacific is known as the Southern Oscillation.

20. Low-Level Winds & Thermocline Depth La Niña: stronger-than-average easterlies lead to a deeper (shallower)-than-average thermocline in the western (eastern) eq. Pacific. El Niño: weaker-than-average easterlies lead to a deeper (shallower)-than-average thermocline in the eastern (western) eq. Pacific.

21. ENSO: A Coupled Ocean-Atmosphere Cycle ENSO is a “coupled” phenomenon: atmosphere drives the ocean and the ocean drives the atmosphere. “Positive Feedback” between ocean and atmosphere. Example: Weaker equatorial trade winds cold water upwelling in the east will decrease  surface warming of the ocean  reduced east-west temperature gradient  Weaker equatorial trade winds

22. What is “Average?” (2) Warm water heats the atmosphere, the air rises, and low-level trade winds converge toward the warm water. Subsiding air occurs in the eastern Pacific basin. Warm Cold December-February Average Conditions Winds and Sea Surface Temperature are COUPLED. The SSTs influence the winds and vice versa. (1) Easterly trade-winds help push warm water to the western Pacific and upwell cold water along the equator in the eastern Pacific Ocean. Warm Cold

23. NOTE: Location of the warmest SSTs (>~28°C) determines where tropical convection will be located. “El Niño” • Convection shifts eastward over the central and/or eastern Pacific Ocean. Convection becomes suppressed over the far western Pacific/ Indonesia. Warm Warm Cold • Easterly trade winds weaken • Thermocline deepens and the cold water upwelling decreases in the eastern Pacific. Warm Cold

24. “La Niña” Enhanced • Convection becomes stronger over the far western Pacific Ocean/ Indonesia and more suppressed in the central Pacific. More Convection Stronger Stronger Upwelling Warm Cold Cold becomes more shallow • Easterly trade winds strengthen • Thermocline becomes more shallow and the cold water upwelling increases in the eastern Pacific. Warm Cold

25. Global El Niño Impacts Impacts are generally more extensive during the northern winter.

26. Typical Global El Niño Impacts

27. Global La Niña Impacts Mid-latitude impacts generally occur during the winter season (NH – DJF; SH- JJA).

28. Typical Global La Niña Impacts

29. ENSO is a naturally occurring phenomenon. Equatorial Pacific fluctuates between warmer-than-average (El Niño ) and colder-than-average (La Niña) conditions. The changes in SSTs affect the distribution of tropical rainfall and atmospheric circulation features (Southern Oscillation). Many areas of the Tropics and Subtropics experience significant impacts during the extreme phases (El Niño and La Niña) of the ENSO cycle. Changes in intensity and position of jet streams and storm activity occur at higher latitudes. Summary

30. Global Distribution of Precipitation 19.3 Regional Wind Systems  Global precipitation can be explained if knowledge of global winds and pressure systems are applied.