Abstract
The El Nino-Southern Oscillation (ENSO)-associated wintertime atmospheric teleconnection patterns in two Pacific decadal oscillation (PDO) phases are investigated using ERA-20C reanalysis data for 1950–2010. A strengthened ENSO-associated Pacific-North American (PNA) teleconnection pattern presents in PDO positive phase, while a West Pacific (WP) pattern over Northwestern Pacific and a squeezed PNA pattern coexist when ENSO occurs in PDO negative phase. The dynamical role of atmospheric transient eddy feedbacks to the teleconnection patterns are highlighted in the present study. When ENSO occurs in PDO positive phase, the uniform strengthened westerly jet anomalies downstream of the climatological main body of jet accompany with energetic transient eddy anomalies over Northeastern Pacific. The transient eddy feedbacks largely enhance and favor the strengthened PNA pattern. When ENSO occurs in PDO negative phase, the strengthened westerly jet anomalies appear to separate into two parts, one locating north of the climatological main body of jet and the other at the downstream. The accompanied transient eddy anomalies also split into two parts. Under such conditions, the transient eddy feedbacks are limited over Northeastern Pacific and favor a weak PNA pattern. However, the transient eddy anomalies over Northwestern Pacific strengthen, and the feedbacks also strengthen and largely contribute to the WP pattern. Moreover, the transient eddy anomalies over Northwestern Pacific seem to be anchored along the anomalously poleward strengthened oceanic subarctic frontal zone (SAFZ) in PDO negative phase. The enhanced atmospheric baroclinicity anomalies, coupled with the strengthened SAFZ, energize atmospheric transient eddy anomalies, and work as the potential maintenance in shaping the WP pattern.
Highlights
El Nino-Southern Oscillation (ENSO), as the dominant pattern of interannual climate variability, greatly influences the atmospheric circulation and triggers a cascade of atmospheric teleconnections around the globe (e.g., Bjerknes1969; Wallace and Gutzler 1981, hereafter WG81; Hoskins and Karoly 1981; Deser and Wallace 1990; Wang 2000)
Other studies have shown the linkage between ENSO and western Pacific (WP) teleconnection pattern (e.g., Horel and Wallace 1981; Koide and Kodera 1999), which was confirmed as the third mode of singular value decomposition (SVD) between the geopotential height and sea surface temperature anomalies (SSTA) in boreal winter
The ENSO-associated wintertime atmospheric teleconnection patterns in two Pacific Decadal Oscillation (PDO) phases are obtained based on the ERA-20C reanalysis data during the period of 1950–2010
Summary
El Nino-Southern Oscillation (ENSO), as the dominant pattern of interannual climate variability, greatly influences the atmospheric circulation and triggers a cascade of atmospheric teleconnections around the globe (e.g., Bjerknes1969; Wallace and Gutzler 1981, hereafter WG81; Hoskins and Karoly 1981; Deser and Wallace 1990; Wang 2000). The WP pattern is a meridional dipole pattern of atmospheric circulation anomalies at the middle/high latitudes of the Northwestern Pacific, related to the meridional shift of the Aleutian Low (Liu and Alexander 2007; Di Lorenzo et al 2015), well known as the major pattern that modulates the East Asian winter monsoon (Takaya and Nakamura 2013) They are usually interpretable as the result of midlatitude stationary wave anomalies associated with the tropical heating related to ENSO and the dynamical adjustment between zonal mean flow and transient eddies both from the theoretical and modeling perspective
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