Nabeel Keblawi METO 658N Dr. Sumant Nigam Dr. Alfredo Ruiz-Barradas

1. Variability of the North American MonsoonAssociated with Preceding Winter’s Snowmass and Pacific SSTs Nabeel Keblawi METO 658N Dr. Sumant Nigam Dr. Alfredo Ruiz-Barradas

2. Overview • Introduction (brief) • Data & Methodology • Climatology/Variability • SWE/Monsoon/Pacific SSTs • Discussion • Conclusion

3. Background Information • Indian Monsoon • North American Monsoon • Connection with neighboring snow cover of the preceding winter. • Blanford Hypothesis: Winter/Spring snow cover in the Himalayas mountain region has an inverse relationship with June-September Indian rainfall.

4. Contradictory results • In recent years there have been contradictions against the Blanford Hypothesis. • Fusallo (2004), Bamzai & Shukla (1999) and Ye & Bao (2001): • Positive correlation between snow cover and monsoonal rainfall anomalies • These results are at odds with the Blanford Hypothesis for the spatial distribution of snow cover.

5. Rationale • Given all these contradictions, there’s the need to determine the driving factors of the monsoon, whether they are: • Antecedent Pacific SST Anomalies – ENSO & PDO • ENSO: Equatorial SST Anomalies in Pacific Ocean • PDO: ENSO-like SST Anomalies in North Pacific • Antecedent Snow Depth Anomalies – SWE • Other factors involved? • Monsoons in North America and India often cause flash flooding that is hazardous and disruptive. • Areas that are prone to severe drought. • Implications on the regional water supply.

6. Data • Snow Depth & Precipitation • NARR: 1° x 1° 1979-2002 • ERA40: 2.5° x 2.5° 1979-2002 • ENSO-MEI & PDO • NOAA-NCEP • Initial comparison between NARR & ERA40 ruled out any differences in correlation between SWE & Precip anomalies due to time differences and resolution. • However, ERA40 snow depth data was concluded to be of lesser quality than the NARR data due to ERA40’s coarse resolution. • Snow depth varies greatly over small spatial areas… • E.g. windward slopes vs. lee slopes on a mountain range

7. Variables • Snow Depth • Units: mm SWE (Snow Water Equivalent) • Surface Convective Precipitation • Units: mm/day • ENSO & NPO indices • Standardized Indices from NOAA-NCEP

8. Spatial Domain • North America: • Latitudes: 20°N-60°N • Longitudes: 140°W-100°W • Areas of highest variability are selected by taking the standard deviation maximums of the anomalies of snow depth and convective rainfall.

9. Methodology • Snow depth (mm SWE): April 1 • Representative of total winter snow accumulations • Convective Precipitation (mm/day): JAS • Climatologies/Anomalies of each variable • Std. dev >0.5 mm/day for July rainfall • Indices: Area-averaged anomalies within selected areas divided by one standard deviation. • Statistical Analysis: Correlations/Regressions

10. SWE Climatology & Variability: April CAN#2 CAN#1 US#1 US#2

11. Precipitation Climatology

12. Precipitation Variability (areas are fixed throughout JAS) North Zone South Zone North & South Zones are fixed throughout JAS

13. NARR: SWE-Monsoon Correlation

14. ENSO & PDO Time Series The correlation between ENSO & PDO is r = 0.79

15. Correlation: Pacific SSTs & SWE Notice the opposite correlations of US vs. Canadian Rockies

16. Regression: Pacific SSTs on SWE CAN#2 CAN#1 US#1 US#2 ENSO – strongest influence on snowfall all over the Rockies

17. Correlation: Pacific SSTs & July Precip In the monsoon zones: little or no correlation for July, but…

18. Correlation: Pacific SSTs & August Precip … significant positive correlations merely one month later! remarkable

19. Correlation: Pacific SSTs & Sept Precip Positive correlations still there…

20. Regression: Pacific SSTs on July Precip Looking at the bars, ENSO has a stronger effect on US precipitation than the PDO.

21. Regression: Pacific SSTs on August Precip A noticeable change from previous month; moisture associated with ENSO/PDO events surges northward well into the US…

22. Regression: Pacific SSTs on Sept Precip Influence from the PDO abates somewhat in September, while that from ENSO stays to the north throughout the last month of monsoon.

23. US1 SWE Regressed on JAS Precipitation Similar pattern to the SWE-monsoon correlation table; no effect in July, then the linkage becomes stronger.

24. US2 SWE Regressed on JAS Precipitation Unlike US1, US2 not significantly linked with the monsoon.

25. C1 SWE Regressed on JAS Precipitation C1 shows inverse relationship with monsoon except perhaps for Sept…

26. C2 SWE Regressed on JAS Precipitation C2 is an interesting case: consistent inverse relationship with monsoon… opposite of US1!

27. Discussion • Snow depth in the US Rockies #1 show strong and consistent positive correlation with the North American Monsoon. • But the antecedent ENSO is also positively correlated with the snow depth in US1, and subsequently with the monsoon. • ENSO  SWE  Monsoon • ENSO  Monsoon • Negative correlation between monsoon and Canadian Rockies snow depth. • Correlation/Regression figures of antecedent Pacific SSTs on Canadian Rockies SWE anomalies supports this with strong negative correlation also.

28. Discussion • These results indicate that Pacific SSTs may be one factor driving the monsoon. • Appears unlikely that SWE is driving the monsoon. • Possible Physical Explanation -- Suppose we have anomalously warm Pacific SSTs: • 1) Through increased evaporation rates overlying anomalously warm waters, this anomalously moist air eventually flows into the monsoon region… • 2) Then we have increased moisture flux convergence in the monsoon region -- moisture advection and increased thermodynamic instability atmos. column… • 3) Orographical effects may also force vertical motion and locally enhance rainfall…

29. Discussion • Canadian Rockies SWE correlation with monsoon opposite of US Rockies SWE. • And the effect of Pacific SSTs on the US Rockies vs. the Canadian Rockies also appears to be opposite of each other: • US Rockies SWE above normal in warm ENSO/PDO. • Canadian SWE below normal in warm ENSO/PDO. • This may explain the “contradictory” results between SWE and the monsoon – they make sense when we consider that the Pacific SSTs are driving the monsoon, not SWE anomalies. • However, this says nothing about the onset of the monsoon, of which the SWE anomalies may still influence via land-sea temperature gradients.

30. Potential for Future Research • The NAM-Pacific SST relationship may be further investigated to determine if the Pacific SSTs are stronger factors in driving the monsoon. • Not just ENSO or PDO … but also the Pacific Warm Pool, ENSO 1+2, ENSO3.4, MJO, etc … • The relationship between SWE and the monsoon may also be investigated on daily-weekly time scales to determine its influence on the onset of the monsoon. • Other variables, such as total column precipitable water, soil moisture, and geopotential height may also be used to further investigate moisture flux convergence, wind strength/direction, and the effects of SWE and Pacific SSTs on the onset and strength of the monsoon.

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