1. Strengthening of the Equatorial Pacific Upper‐Ocean Circulation Over the Past Three Decades.
- Author
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Tuchen, Franz Philip, Perez, Renellys C., Foltz, Gregory R., McPhaden, Michael J., and Lumpkin, Rick
- Subjects
EL Nino ,OCEAN waves ,SOUTHERN oscillation ,LA Nina ,WATER masses - Abstract
Thirty years (1993–2022) of concurrent satellite and in‐situ observations show a long‐term strengthening of the equatorial Pacific upper‐ocean circulation. Enhanced southeasterly and cross‐equatorial winds have caused an annual mean, basin‐wide acceleration of the equatorial westward near‐surface currents by ∼20% and an acceleration of poleward flow north (south) of the equator by ∼60% (∼20%). Additional moored velocity data reveal a deepening of the Equatorial Undercurrent (EUC) core at 170°W and significant shoaling at 140°W and 110°W, but no significant changes in EUC core velocity. The strongest subsurface zonal velocity trends are observed above the EUC core in the central to eastern Pacific and occur before and after the seasonal maximum of EUC core velocity, causing enhanced upper‐ocean vertical current shear. Consistent with trends of the 20°C isotherm depth along the equatorial Pacific, a significant basin‐wide steepening of the equatorial thermocline is observed. Both the accelerating equatorial current system and the enhanced thermocline slope are consistent with an observed steepening of the zonal sea surface height gradient due to increased wind‐driven westward mass transport at the surface. During February‐March, both surface and subsurface currents along the equator show eastward velocity trends, in contrast to westward near‐surface current trends during the remainder of the year. The trend reversal is attributed to both a long‐term shift in equatorial Kelvin wave activity and to the impact of strong interannual variability due to El Niño Southern Oscillation and other modes of natural variability on decadal to multidecadal time scales. Plain Language Summary: Thirty years (1993–2022) of temporally overlapping satellite and in‐situ observations reveal a long‐term strengthening of the equatorial Pacific circulation in the upper 200 m. Both the west‐east (zonal) and south‐north (meridional) surface atmospheric winds typically observed in the tropical Pacific intensified. As a result, westward near‐surface currents in the central equatorial Pacific accelerated by ∼20%, while poleward currents accelerated by ∼60% (∼20%) north (south) of the equator. The strongest trends in zonal velocity are observed above the core of the Equatorial Undercurrent. While the subsurface current in the central and eastern Pacific shoaled by 12 m, it deepened in the western Pacific by 6 m, which aligns with trends of the 20°C isotherm depth. Both the accelerating equatorial currents and the steeper thermocline slope are consistent with a steepening west‐east slope of sea surface height due to increased westward water mass transport. Our results show that a shift in equatorial wave activity and strong interannual variability cause eastward velocity anomalies in the observed surface and subsurface current trends during February‐March. Between 1993 and 2022, long‐term equatorial circulation trends persist, but these trends are modified by natural events at both interannual timescales such as El Niño and La Niña events, and longer timescales. Key Points: 30 years of observations show a wind‐driven strengthening of equatorial Pacific surface zonal currents by ∼20% and poleward flow by ∼20%−60%The subsurface Equatorial Undercurrent intensified above its core depth, primarily in the central to eastern PacificLong‐term moored observations of subsurface velocity and temperature show a significant basin‐wide steepening of the equatorial thermocline [ABSTRACT FROM AUTHOR]
- Published
- 2024
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