Teleconnections
Circulation patterns like NAO are often associated with global teleconnections through propagation of Rossby wave trains. El Nino-Southern Oscillation (ENSO) events, Sudden Stratospheric Warmings (SSW) and pronounced Madden-Julian Oscillation (MJO) events have been found to enhance the predictability and skill of forecast circulations in the North Atlantic/European area.
In particular, the presence of and the phases of significant MJO events can be linked to an increase of skill in forecasting NAO– circulation patterns Fig8.2.8-1 compares the bivariate correlation (NAO & BLO) against analysis for forecasts initiated with and without an MJO event. Forecasts initiated with an MJO event show higher skill (an improvement of the order of one day) between Day8 and Day15. Correlations are significantly increased for Day11 and Day12 at a 90% confidence level, and for Day10 to Day13 at an 80% confidence level.
Some broad remarks can be made:
- The probability of the development of a positive NAO signal is significantly increased about ten days after the MJO is in phase 3 (i.e. enhanced convection over the Indian Ocean), and significantly decreased about ten days after the MJO is in phase 6 (i.e. enhanced convection over the Western Pacific and suppressed convection over Indian Ocean).
- The probability of the development of a negative NAO signal is significantly decreased about ten days after the MJO is in phase 3 (i.e. enhanced convection over the Indian Ocean), and significantly increased about ten days after the MJO is in phase 6 (i.e. enhanced convection over the Western Pacific and suppressed convection over Indian Ocean).
- The impact of the MJO on two other Euro-Atlantic weather regimes (the Atlantic Ridge and Scandinavian blocking) is much weaker.
Research has shown that in the winter half of the year the reliability of 2m temperature forecasts for Europe is influenced by whether or not there is a substantive MJO at analysis time. The IFS can model the evolution of a pre-existing MJO quite well and also can also capture the consequent influence at mid-latitude effects. However, the IFS has trouble generating new, substantive MJOs in the right place, which then impedes the predictive skill when there is no MJO at start time.
Thus the 2m temperature anomaly forecasts for Europe tend to be:
- more reliable if there is a substantive MJO at analysis time, (i.e. lying outside the circle on the Wheeler-Hendon diagram).
- less reliable if there is not a substantive MJO at analysis time.
Forecasters should be able to use these results to good effect when examining the monthly forecasts.
Fig8.2.8-1: Bivariate correlation (NAO & BLO) for forecasts with (red) and without (black) an MJO event in the initial conditions. Colours refer to initial conditions for the forecasts:
- black - no initial MJO.
- red - initiated with an MJO (shows higher skill between Day8 and Day15).
Fig8.2.8-2: Brier Skill Scores (BSS) for NAO– predictions according to the initial MJO phase. Colours refer to initial conditions for the forecasts:
- black - no initial MJO.
- red - MJO phases 2–3 (enhanced convection over the Indian Ocean).
- blue - MJO phases 4–5 (enhanced convection over the Maritime Continent).
- green - MJO phases 6–7 (enhanced convection over the western Pacific).
- brown - MJO phases 1 and 8 (suppressed convection over the Maritime Continent).
The MJO influences skill in forecasts concerning NAO– circulation pattern:
- During MJO phases 4&5 skill is increased for the Day13-20 period.
- During MJO phases 6&7 skill is increased for the Day8-13 period.
The corresponding increases in skill for NAO+, BLO+ and BLO– are small.
Fig8.2.8-3: Variation of the MJO index bivariate correlation with forecast lead-time for two older ECMWF model cycles (40r1 and 40r3). Beyond Day20 correlation falls below 0.7. By Day 27 it falls below 0.6, implying marginal skill.
MJO Teleconnection Example
The forecast based on 00UTC 12 Jan 2024 illustrates the tele-connection effect of tropical deep convection over the Indian Ocean upon subsequent downstream developments of NAO+ type over the North Atlantic/Europe.
Fig8.2.8-4: MJO Wheeler-Hendon diagram for the monthly forecast based on DT 00UTC 12 January 2024. The colours represent ENS forecasts at various lead times as given by the key above the diagram. The ENS forecasts of the MJO show a steady progress westward but with increasing spread. The forecasts for MJO are:
- initially in Sector3 (Western Indian Ocean) with a small spread among ENS members.
- by Day5 in Sector4 (Eastern Maritime Continent) with only a limited spread among ENS members maintaining high confidence.
- by Day15 to Day20 in Sectors 6 and 7 Western Pacific) with an increasingly large spread showing fairly high confidence in location but lower for intensity. ENS members lying within the internal circle correspond to very weak MJO.
Fig8.2.8-5: Euro-Atlantic weather regime projection Wheeler-Hendon diagram (NAO/BL phase space diagrams) for the monthly forecast based on DT 00UTC 12 January 2024. As the MJO progresses westward (Fig8.2.8-4), the downstream teleconnection influences changes in the Euro-Atlantic weather regime. The Euro-Atlantic weather regime is predominantly NAO- initially on 15-21 Jan but is forecast to evolve into NAO+ by 22-28 Jan.
There is not strong preferential path leading to NAO+ regime, but the chances of NAO+ Euro-Atlantic weather regime increase 10 days after the MJO is in phase 3.
Fig8.2.8-6: The Euro-Atlantic weather regime presented in histogram form reflecting the regime projection diagrams (Fig8.2.8-5) above. The regime is generally NAO-(green) 15-21 Jan but is forecast to evolve into predominantly NAO+ (blue) by 11-17 Jan.
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(Note: In older material there may be references to issues that have subsequently been addressed)
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