Abstract
Intraseasonal Kelvin waves (IKWs) and Tropical Instability Waves (TIWs) are essential components of the tropical Pacific coupled climate variability. While downwelling IKWs are precursors of ENSO (e.g., the El Niño Southern Oscillation), TIWs contribute to its asymmetry by mixing more/less warm off-equatorial and cold tongue waters during La Niña/El Niño. Theoretical studies and a few observational case studies also suggest that TIWs and IKWs can interact non-linearly. However, owing to the chaotic nature of TIWs, observational evidence that such a process occurs consistently has not been established thus far. Here, we document for the first time their interaction from satellite observations over a period spanning almost 30 years (1993–2018). From complex empirical orthogonal functions analysis and sea level decomposition into meridional modes, we evidence that a substantial share (∼42%) of the variance of TIWs-induced intraseasonal sea level anomalies are associated with IKWs activity. We show that non-linear dynamical heating (NDH) in the Eastern equatorial Pacific associated with this intraseasonal mode can be as large as that for interannual time scales. Implications for understanding the eastern tropical Pacific heat budget and ENSO variability are discussed.
Highlights
Tropical instability waves (TIWs) are unique westward-moving cusp-shaped mesoscale features first observed via infrared satellite systems by Legeckis (1977) in particular along the strong meridional Sea Surface Temperature (SST) gradient in the eastern equatorial Pacific
The enhanced meridional heat transport associated with Tropical Instability Waves (TIWs) during La Niña; compared to El Niño has been shown to contribute to the El Niño–Southern Oscillation (ENSO) asymmetry characterized by larger-amplitude El Niño than La Niña events (An, 2008; Imada and Kimoto, 2012; Boucharel and Jin, 2020; Xue et al, 2020, 2021), which can in turn feedback onto the Pacific decadal variability (Rodgers et al, 2004; Yeh and Kirtman, 2004, 2005; Choi et al, 2009, 2011, 2013; Ogata et al, 2013; Capotondi et al, 2020; Zhao et al, 2021)
The maximum correlation between sea level anomalies reconstructed from CEOF1 and CEOF2 is reached (r = 0.3 between 2◦S–2◦N and 170–120◦W) at a positive lag of 14 days [Principal Component (PC) 1 lags PC2], corresponding to about a quarter of the main period of Intraseasonal Kelvin waves (IKWs), which confirms that the two modes capture the same sequences of IKWs
Summary
Tropical instability waves (TIWs) are unique westward-moving cusp-shaped mesoscale features first observed via infrared satellite systems by Legeckis (1977) in particular along the strong meridional Sea Surface Temperature (SST) gradient in the eastern equatorial Pacific. We assume like in former studies based on satellite sea level (Boulanger and Menkes, 1995; Perigaud and Dewitte, 1996) that the oceanic vertical structure along the equator can be accounted for by just the first baroclinic mode, so that, total sea level (h) and zonal current (u) anomalies can be expressed as a linear combination of meridional mode functions accounting for Kelvin and Rossby waves.
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