1. More Ocean Indices Paul Knight, Richard Grumm and Paul Roundy
PSU Meteorology and NWS
State College

2. Pacific Decadal Oscillation PDA/NPO Oceanic Index
The Pacific Decadal Oscillation (PDO) is an index of long-term variability of the sea-surface temperatures of the North Pacific Ocean.
reflects the dominant mode of SST over the North Pacific Ocean.
The PDO can impact the climate.
A characteristic that distinguishes the PDO from ENSO is that 20th century PDO events have tended to persist for 20-to-30 years, while ENSO events have typically persisted for 6 to 18 months.
also known as the North Pacific Oscillation (NPO) and the terms can be used interchangeably.

3. Phases of the PDO/NPO
the high phase of the NPO is the term used to describe a warm PDO and the low phase of the NPO is the term used to describe the cold PDO.
Recent research indicates a clear link of the PDO to the ENSO. The Climate Prediction Center thinks that the sign of the PDO may be a composite of a longer term ENSO cycle.

4. PDO SST Examples

5. The cold phase Cold PDO regimes prevailed from 1890-1950
cold phase index is positive
the PDO was higher then average from 1920 to 1950.
cold phase may behave like a weak La Nina
note colder water in tropical Pacific dominates
may enhance impacts of La Nina when they are in phase
The cold phase occurs when there is warmer water over the western and central Pacific associated with a deepened Aleutian low.
Colder water over eastern and tropical Pacific

6. The warm phase Warm PDO regimes dominated from 1950 into the 1990’s.
During the warm phase, the PDO is negative.
On a 30 year time scale, the PDO was lower than average from 1950 to 1980.
A negative PDO may act like an El Nino.
The warm phase occurs when there is colder water over the western and central Pacific.

7. The warm phase
Warmer and drier winters in the northern regions of the nation and wetter and cooler winters observed in the southern areas of the United States.
El Nino is associated with a negative SOI, weak tropical easterlies and warm Nino3.4 SST’s.

8. PDO SST/wind vectors/MSLP anomalies

9. PDO-ENSO Similarities SST/wind vectors/MSLP anomalies

10. PDO values

11. PDO Summary Relates to ENSO cycles High NPO (warm phase)
Frequency of El Nino can be related to PDO phase during the past years.
PDO can interfere both constructively and destructively with ENSO.
PDO may not be independent of ENSO
High NPO (warm phase)
Cold water in north/central Pacific
Warm water along west coast NOAM (fishing industry named phases!)
May enhance El Nino effects in eastern US
Low NPO (cold phase)
Warm water in north/central Pacific
La Nina like impact connect with weaker storm tracks, farther north [dry-nation]

12. Referemces
Rogers, J.C., 1997: North Atlantic storm track variability and its association to the North Atlantic Oscillation and climate variability of Northern Europe. Journal of Climate 10(7),
Hurrell, J.W., 1995: Decadal trends in the North Atlantic Oscillation and relationships to regional temperature and precipitation. Science 269,
Wallace, J.M. and David S. Gutzler, 1981:"Teleconnections in the Geopotential Height Field during the Northern Hemisphere Winter" Mon. Wea. Review,109,
Teleconnections Linking Wolrdwide Climate Anomalies. ed. M.H. Glantz, R.W. Katz and N. Nicholls, Cambridge University Press, 1991.
Rogers, J.C. and H. Van Loon, 1979: "The Sea-Saw in winter temperatures between Greenland and Northern Europe. Part II. Some atmospheric and oceanic effectes in middle and high latitudes." Mon Wea. Rev. ,107,

13. The Large-Scale Convective Disturbance
Tropical Intraseasonal or
Madden-Julian Oscillation

14. What is the MJO?
Large-scale disturbance of deep convection and winds that controls up to half of the variance of tropical convection in some regions
Brief history

15. MJO- an intraseasonal event
Prior to 1971, it was thought that virtually all variability in the weather conditions within a given season in the Tropics was random.
There were indications of interseasonal variations, such as the Southern Oscillation
Studies of Tropical rainfall and pressure changes showed additional oscillations

16. The MJO - A Description
A day oscillation in the coupled Tropical ocean-atmosphere system
An eastward progression of enhanced and suppressed convection
Low level and upper level wind patterns show distinct anomalies
Strong year to year variability in MJO that is related to ENSO cycle

17. Wave Cooperation
Kelvin and Rossby waves linked by convection, land, and air-sea interaction combine to produce the observed disturbance.

18. Schematic of Mature MJO

19. The 3D view of MJO
Axis of coupled convection/suppressed convection usually between 5S-5N
SST feedback could be sensitive enough to either trigger or help propagate the wave

20. Kelvin Waves in the Ocean

21. Convective Kelvin Wavez
Convection removes
Some of the accumulating
mass, slows propagation H L x
Propagation speed: less than 20 ms-1

22. MJO Statistics
Eastward propagation, 4 +/- 2 ms-1. Also has standing wave behavior
30-60 day period
Wavenumber 1-4 (planetary scale)
Interacts with midlatitudes, but some of this is nonlinear and hard to quantify

23. Finding the MJO

24. The Satellite View of MJO
The MJO is noted by a cluster of thunderstorms drifting eastward along the equatorial Indian and Pacific oceans.

25. Simplified Madden-Julian Oscillation Composite
OLR from A.J. Matthews, 2000.

26. The Velocity Potential View
The 200 mb velocity potential illustrates yet another way of detecting both the presence and movement of the MJO. This is noted by a couplet of anomalies.

27. Disturbances in the 500mb Flow
Another method of detecting the presence of the MJO is following height and wind perturbations in the 500 mb flow over the equatorial Pacific ocean.

28. How Does It Propagate? Is a matter of debate, but, probably involves
interactions with equatorial waves
Kelvin wave
Equatorial Rossby wave
Feedbacks from convection
Sea surface temperatures—air-sea interaction
Land interactions

29. MJO - Probable Cause Wave-CISK Theory (Chang, Lau, Lim)
slow moving wave with conditional instability of the second kind (see Tropical Meteo)
Evaporation-wind feedback Theory (Emanuel, Neelin, Wang)
diabatic heating due to cumulus convection nearly balanced by adiabatic cooling

30. Relationship of MJO to North American Weather
Most prominent connection to phase of ENSO
Winter weather along the West Coast (see figure)
Secondary downstream effects in USA
Modulation of tropical storm development in Atlantic basin during the summer

31. The MJO and West Coast Wx

32. Decay Region
Formation
Region

33. Active
Convection

34. Enhanced
Easterlies
Active
Convection

35. Deflected
Jet Stream
Active
Convection
Energy Build-up

36. Cold air outbreak enhancement
Active
Convection

37. MJO - A Modeler’s Nightmare
GCM simulation of convection (CPS)
SST variations not well simulated
Change of phase speed from eastern to western hemispheres
Handling of very low wave number
Recent modifications-
increased vertical resolution
better parameterization of:
radiation
convection
cloud formation
precipitation
surface convergence

38. Prediction of MJO
Global weather models predict it with some skill to about 7 or 8 days
Filtering methods allow prediction up to 20 days (Wheeler and Weikmann, 2001)
Statistical schemes may allow prediction for more than 40 or 50 day lead times

39. MJO Research Chang, Lim, 1988: Kelvin wave-CISK
Chen, Murakami, 1988: Development and life-cycle of the Indian monsoon
Crum, Dunkerton, 1994: CISK and evaporational-wind feedback
Ferranti, Palmer, Molteni and Klinker,1990: Tropical and extra-tropical interactions associated with day oscillation
Gray,1988: Seasonal frequency variations in the day cycle