Abstract
The mechanism for asymmetric atmospheric responses to the central Pacific (CP) El Niño and La Niña over the western North Pacific (WNP) is studied in this paper. The negative anomalies of rainfall over the key region of WNP are explained by diagnosing the column-integrated equations of moisture and moist static energy (MSE). It is revealed that the nonlinear advection of moist enthalpy is critical to introduce negative rainfall anomalies over the region. The anomalous easterly (westerly) in La Niña (CP El Niño) causes negative advection of anomalous moist enthalpy, inducing negative heating anomaly and an anticyclone anomaly in the WNP, which weakens (strengthens) the cyclone (anticyclone) in La Niña (CP El Niño). The MSE budget analysis shows a larger nonlinear term in CP El Niño than in eastern Pacific (EP) El Niño, inconsistent with the amplitudes of sea surface temperature anomalies. The reason is that the nonlinear term transforms to positive above 700 hPa in EP El Niño, offsetting the negative advection below 700 hPa and thus making the nonlinear term smaller. The nonlinear term is negative at low levels in CP El Niño, resulting in a larger nonlinear term. The stronger precipitation anomalies in the WNP during EP El Niño can be attributed to the linear moist enthalpy advection. The mean easterly wind at mid levels causes a larger (smaller) positive moist enthalpy advection in CP (EP) El Niño, due to a larger (smaller) moist enthalpy gradient, resulting in a positive (negative) linear moist enthalpy advection, which weakens (strengthens) the negative precipitation anomalies in the key region.
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Supported by the National Natural Science Foundation of China (41630423 and 41875069), National Basic Research and development (973) Program of China (2015CB453200), National Science Foundation of U.S. (AGS-1565653), NOAA of U.S. (NA18O AR4310298), Jiangsu Provincial Science Foundation of China (BK20180811), and University of Hawaii (1) School of Ocean and Earth Science and Technology (SOEST) contribution (10750), (2) International Pacific Research Center (IPRC) contribution (1390), and (3) Earth System Modeling Center (ESMC) contribution (269).
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Chen, M., Li, T. & Wang, X. Asymmetry of Atmospheric Responses to Two-Type El Niño and La Niña over Northwest Pacific. J Meteorol Res 33, 826–836 (2019). https://doi.org/10.1007/s13351-019-9022-0
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DOI: https://doi.org/10.1007/s13351-019-9022-0