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Three cases: (1) La Nina event in 1989 (2) A strong El Nino in 1998

Three cases: (1) La Nina event in 1989 (2) A strong El Nino in 1998 (3) A moderate El Nino in 1987 Three fields: (a) Surface temperatures and anomalies ( b ) Sea level pressure and anomalies ( c ) Precipitable water and anomalies. Colder than average. Lower than average pressure.

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Three cases: (1) La Nina event in 1989 (2) A strong El Nino in 1998

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  1. Three cases: (1) La Nina event in 1989 (2) A strong El Nino in 1998 (3) A moderate El Nino in 1987 Three fields: (a) Surface temperatures and anomalies (b) Sea level pressure and anomalies (c) Precipitable water and anomalies

  2. Colder than average

  3. Lower than average pressure

  4. Drier than average

  5. Not all events have same amplitude…best to think of an analogy between El Nino and La Nina and summer and winter: there are things common to each winter to make it a useful concept, but each one is different owing to different weather, different amplitudes of temperature extremes, etc. El Ninos, particularly strong ones, are generally confined to a single 12 month interval. La Ninas may persist for a few consecutive years, so there the oscillation is not linear in nature.

  6. NOAA/NCEP/CPC

  7. NOAA/NCEP/CPC

  8. NOAA/NCEP/CPC

  9. Westerly Wind Bursts (like from an MJO) cause an ocean response

  10. Delayed Oscillator Theory • Initially, Kelvin is downwelling (bringing warmer SSTs), and Rossby is upwelling • Rossby is much slower than Kelvin • At reflection, wave type shift • Key: The reflected Rossby from maritime continent becomes an UPWELLING Kelvin • “Seeds of its own demise” • If this were the only thing happening, would get a very regular oscillation

  11. A real example

  12. There must be more… • Clearly there must be other companion mechanisms, with input from atmosphere, to get us to 3-5 (2-7) year irregular cycles • The original feedback theory • Recharge/discharge theory – Heat builds up in the equatorial region, discharged eastward and poleward during El Niño • Lots of other theories (text), and active research

  13. Monitoring • 3.4 is frequently used because of signal of both convection and SST • 1&2 warm first!

  14. SOI = Tahiti - Darwin (normalized)

  15. Niño Region SST Departures (oC) Recent Evolution The latest weekly SST departures are: Niño 4 -1.2ºC Niño 3.4 -1.6ºC Niño 3 -1.8ºC Niño 1+2 -2.0ºC

  16. SOI and Nino 3-4 index

  17. Jet stream configur-ations

  18. Global Effects

  19. North American Effects Mean number of days per season (November - March 1948 through 1993) in which precipitation exceeded 0.50 inches for Neutral years (top). Lower left map is the difference in this quantity between El Niño years and Neutral years. Lower right map is the difference in this quantity between La Niña years and Neutral years.

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