Abstract
The study of resonantly forced baroclinic waves in the tropical oceans at mid-latitudes is of paramount importance to advancing our knowledge in fields that investigate the El Niño–Southern Oscillation (ENSO), the decadal climate variability, or the resonant feature of glacial-interglacial cycles that are a result of orbital forcing. Indeed, these baroclinic waves, the natural period of which coincides with the forcing period, have a considerable impact on ocean circulation and in climate variability. Resonantly Forced Waves (RFWs) are characterized by antinodes at sea surface height anomalies and nodes where modulated geostrophic currents ensure the transfer of warm water from an antinode to another, reflecting a quasi-geostrophic motion. Several RFWs of different periods are coupled when they share the same node, which involves the geostrophic forces at the basin scale. These RFWs are subject to a subharmonic mode locking, which means that their average periods are a multiple of the natural period of the fundamental wave, that is, one year. This property of coupled oscillator systems is deduced from the Hamiltonian (the energy) of the Caldirola–Kanai (CK) oscillator. In this article, it is shown how the CK oscillator, which is usually used to develop a phenomenological single-particle approach, is transposable to RFWs. Subharmonic modes ensure the durability of the resonant dissipative system, with each oscillator transferring as much interaction energy to all the others that it receives periodically.
Highlights
The resonance of baroclinic waves in the stratified oceans is a topic that motivates sustained research, be it equatorial or off-equatorial waves
Coupled multi-frequency baroclinic waves are ubiquitous whether they develop in tropical oceans or at mid-latitudes
Subharmonic mode locking occurs from the fundamental Quasi-Stationary Waves (QSWs) whose natural period coincides with the forcing period, that is, one year, which is the duration of the revolution of the earth around the sun
Summary
The resonance of baroclinic waves in the stratified oceans is a topic that motivates sustained research, be it equatorial or off-equatorial waves. The study of resonantly forced baroclinic waves in the tropical oceans at mid-latitudes is of paramount importance to advancing our knowledge in fields that investigate the El Niño–Southern Oscillation (ENSO), the decadal [12] and, probably, long-term climate variability. These baroclinic waves, the natural period of which coincides with the forcing period, have a considerable impact on the climate since the oscillation of the pycnocline depth causes the displacement of warm subsurface water masses. Ocean-atmosphere interactions are enhanced by increasing the thermal gradient in the upper ocean as well as the moisture content in the atmosphere
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