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IBS, Seoul, Korea, August 5, 2013

IBS, Seoul, Korea, August 5, 2013. Predictability and Prediction of Monsoons in the Present and the Future Climate. Jagadish Shukla Department of Atmospheric, Oceanic and Earth Sciences (AOES) George Mason University (GMU) Center for Ocean-Land-Atmosphere Studies (COLA)

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IBS, Seoul, Korea, August 5, 2013

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  1. IBS, Seoul, Korea, August 5, 2013 Predictability and Prediction of Monsoons in the Present and the Future Climate Jagadish Shukla Department of Atmospheric, Oceanic and Earth Sciences (AOES) George Mason University (GMU) Center for Ocean-Land-Atmosphere Studies (COLA) Institute of Global Environment and Society (IGES)

  2. Great Famine of 1876-78 (India)

  3. All India Monsoon Rainfall: -29% Drought Area: 670,000 km² Estimated Deaths (Wikipedia): 5.5 – 8.2 million Governance: British Rule (Lord Lytton exported food from India to England) Great Famine of 1876-78 (India) About 13 million people died in China Late Victorian Holocausts (2001) by Mike Davis El Nino Famines and the Making of the Third World

  4. SST Anomaly (°C) for DJF 1877 Courtesy of Lakshmi Krishnamurti

  5. Outline • Statistical Prediction • Predictability of Seasonal Mean • Fidelity of Models • ENSO-Monsoon • Dynamical Prediction • Summary

  6. What Determines The Limits Of Weather And Climate Prediction? • Weather Prediction: • Accuracy of observations to describe current weather • Realism of physical-dynamical models • Chaos: sensitive dependence on initial conditions

  7. ECMWF: Skill of deterministic forecasting systems, 1980-2010

  8. ERA Forecast Verification Center of Ocean-Land-Atmosphere studies Anomaly Correlation of 500 hPa GPH, 20-90N

  9. What Determines The Limits Of Weather And Climate Prediction? • Seasonal Prediction: • Weather prediction and: • Global sea surface temperature, snow, soil wetness • Coupling of ocean-atmosphere-land • Power of computers

  10. Dynamical Seasonal Prediction (DSP)Source of predictability: Dynamical memory of atmos. IC + Boundary forcing (SST, SW, snow, sea ice) DSP = NWP + IC of Ocean, Land, Atmosphere − dynamically coupled and consistent IC − Global ocean (especially upper ocean); sea ice (volume) − Global Atmos. including stratosphere (IC) − Global GHG (especially CO2, O3) − Global land (soil moisture, vegetation, snow depth) IC Tier 1: Fully coupled models (CGCM) to predict Boundary Forcing Tier 2: Predict Boundary Forcing separately; use AGCM • (NWP=Atmos. IC + SST IC)

  11. Predictability of Time (Seasonal) Mean

  12. Analysis of Variance: F as a measure of predictability 5 CGCMs, 46 years, 9 ensembles

  13. F-values for JJAS precip. For 46-years and 9 ensemble members the 5% significance is F=1.4. Gray color indicates not statistically significant at 95% confidence interval.

  14. Center of Ocean-Land-Atmosphere studies Hypothesis • Models that simulate climatology “better” • make better predictions. • Definition: Fidelity refers to the degree to which the climatology of the forecasts (including the mean and variance) matches the observed climatology

  15. Center of Ocean-Land-Atmosphere studies Climate Model Fidelity and Predictability • Relative Entropy: The relative entropy between two distributions, p1(x) and p2(x), is defined as • (1) • where the integral is a multiple integral over the range of the M-dimensional vector x. • (2) • where jk is the mean of pj(x) in the kth season, representing the annual cycle, j is the covariance matrix of pj(x), assumed independent of season and based on seasonal anomalies. The distribution of observed temperature is appropriately identified with p1, and the distribution of model simulated temperature with p2.

  16. Center of Ocean-Land-Atmosphere studies Fidelity vs. Skill Courtesy of Tim DelSole

  17. Center of Ocean-Land-Atmosphere studies OBS CMCC UKMO Met.Fr IFM ECMWF Box- and whisker- plot of JJAS all India rainfall (mm) for 1960-2005: Observed (IITM) and hindcasts from ENSEMBLES project. Centerline is the median, first and last quartile as the ends of the rectangle, and data not included in the whiskers are open circles.

  18. Model Bias

  19. Dynamical Seasonal Prediction ENSO-Monsoon Relationship

  20. ENSO has large amplitude after the monsoon season: to predict monsoon, we must predict ENSO first

  21. J J A S

  22. 21-year running cc: obs. all India JJAS rainfall and July NINO3 (top left); Simulated pairs of bi-variate random variables with population correlation -0.54 (top right, bottom left) where x and w are independent, normally distributed random variables with unit variance, and ρ is a constant (less than or = 1). Population correlation between random pairs of variables (x and y) produced by this model, will be equal to ρ.

  23. Center of Ocean-Land-Atmosphere studies OBS CMCC UKMO Met.Fr IFM ECMWF Box- and whisker- plot of JJAS all India rainfall (mm) for 1960-2005: Observed (IITM) and hindcasts from ENSEMBLES project. Centerline is the median, first and last quartile as the ends of the rectangle, and data not included in the whiskers are open circles.

  24. Running 21-year correlations between observed ISMR and observed July NINO3 (thick black), between ensemble mean ISMR and ensemble mean JJAS NINO3 (colored solid lines), and between ISMR and JJAS NINO3 of a selected ensemble member from each model (dots connected by solid lines). All-India rainfall in dynamical models is defined as the total land precipitation within 70E − 90E and 10N − 25N. The center year of the 21-year period is plotted on the horizontal axis. The 5% significance threshold for a 21-year correlation is shown as a thin horizontal black line.

  25. Center of Ocean-Land-Atmosphere studies (46 years (1960-2005); Ens.=9) For 1960-2005 Obs, CC (April Nino3, ISMR): −0.18 CC (May Nino3, ISMR): −0.21 Correlation between observed and predicted JJAS all-India rainfall for hindcasts in the ENSEMBLES data set for the period 1960-2005. All-India rainfall in dynamical models is defined as the total land precipitation within 70E − 90E and 10N − 25N . Last row shows empirical prediction using observed May NINO3.

  26. Correlation between Observed and Predicted NINO3 Correlation between observed NINO3, and ensemble mean NINO3 predicted by the ENSEMBLES models, for hindcasts in the period 1960-2005, as a function of calendar month. Also shown is the correlation between observed NINO3 and the least squares prediction of NINO3 based on the observed May NINO3 value (thick grey). The ‘x‘-symbols on the far right give the correlations between the observed and predicted JJAS NINO3 index.

  27. Correlation between Observed JJAS all India rainfall and Model NINO3

  28. Summary (not shown) • The apparent breakdown of ENSO – Monsoon correlation could be due, in large part, to sampling variability. • Realistic Land ICs enhance weekly-monthly predictions (high resolution land rainfall data required) • Model predictability depends on model’s fidelity to simulate climate. • Realistic simulation of diabatic heat sources in West-Pac. & IO will be required for accurate ISO and seasonal prediction.

  29. Summary Model’s ability to simulate SST and Q in West Pacific and Indian Ocean are critical for accurate monsoon prediction. Predictability (Analysis of Variance, F test) calculation for 5 coupled model (“ENSEMBLES” Project) seasonal predictions for 46 years, 9 member ensembles: (ISMR is predictable at 95% significance) Skill of coupled O-A models for predicting ISMR for 1960-2005 is significant at 95%. (Coupled O-A models for monsoon prediction is the future.)

  30. Summary • ENSO prediction skill is sensitive to ocean IC (NCEP, ECMWF). • AGCM forced with SST predicted by coupled O-A models have comparable ACC, but larger RMSE and variance. (coupling damps the heat flux variability) • The lack of skill in monsoon forecasts is not due to intrinsic limits of predictability, but due to insufficient data, inaccurate models, insufficient computing power, and lack of well-trained scientific capacity. (a la NWP: large dedicated effort; slow & steady progress)

  31. Influence of IC on Seasonal Prediction Zhu et al. (GRL, 2012)

  32. Towards a Hypothetical “Perfect” Model • Replicate the statistical properties of the past observed climate • Means, variances, covariances, and patterns of covariability • Utilize this model to estimate the limits of predicting the sequential evolution of climate variability • Better model  Better prediction (??) Center of Ocean-Land-Atmosphere studies

  33. Center of Ocean-Land-Atmosphere studies Seamless Prediction of Weather and Climate From Cyclone Resolving Global ModelstoCloud System Resolving Global Models • Planetary Scale Resolving Models (1970~):Δx~500Km • Cyclone Resolving Models (1980~):Δx~100-300Km • Mesoscale Resolving Models (1990~):Δx~10-30Km • Cloud System Resolving Models (2000 ~):Δx~3-5Km Mesoscale System Organized Convection Cloud System Synoptic Scale Planetary Scale Convective Heating MJO ENSO Climate Change

  34. THANK YOU! ANY QUESTIONS?

  35. Monsoon in a Changing Climate • There are many complex climate models in the world which have calculated the projected changes in the Indian monsoon rainfall in the 21st century. • Most of the models are projecting that in the worst case scenario of very high emissions and high global warming (3-4 °C) long-term mean monsoon rainfall for the 21st century, over the entire Asian region, will be the same or more than that in the current climate. • There will be much larger year to year variability (floods and droughts)

  36. 23 IPCC Global Climate Models

  37. JJAS Rainfall Difference (mm/day) due to Climate Change (RCP8.5, 2071-2099) JJAS Surf Temp Difference (°C) due to Climate Change (RCP8.5, 2071-2099)

  38. JJAS Difference due to Climate Change (RCP8.5, 2071-2099) Temperature (°C) Rainfall (mm/day)

  39. THANK YOU! ANY QUESTIONS?

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