Abstract
Abstract. Over the last decades, the Humboldt Current upwelling ecosystem, particularly the northern component off the coast of Peru, has drawn the interest of the scientific community because of its unique characteristics: it is the upwelling system with the biggest catch productivity despite the fact it is embedded in a shallow and intense oxygen minimum zone (OMZ). It is also an area of intense nitrogen loss and anammox activity and experiences large interannual variability associated with the equatorial remote forcing. In this context, we examined the oceanographic and biogeochemical variability associated with the OMZ off central Peru from a monthly time series (1996–2011) recorded off the coast of Callao (12° 02′ S, 77° 29′ W). The data reveal a rich spectrum of variability in the OMZ that includes frequencies ranging from seasonal to interannual scales. Due to the efficient oceanic teleconnection off Peru, the observed variability is interpreted in the light of an estimate of the equatorial Kelvin wave contribution to sea level anomalies considering the peculiarities of its vertical structure (i.e., the first two baroclinic modes). The span of the data set allows us to contrast two OMZ regimes. The strong regime is associated with the strong 1997–1998 equatorial Pacific El Niño, during which the OMZ adjusted to Kelvin-wave-induced downwelling conditions that switched off the upwelling and drastically reduced nutrient availability. The weak regime corresponds to the post-2000 period associated with the occurrence of moderate central Pacific El Niño events and enhanced equatorial Kelvin wave activity, in which mean upwelling conditions are maintained. It is shown that the characteristics of the coupling between physics and biogeochemistry is distinct between the two regimes with the weak regime being associated with a larger explained variance in biogeochemical properties not linearly related to the ENSO oceanic teleconnection. The data also reveal a long-term trend from 1999 corresponding to a deepening of the oxygen-deficient waters and warming. The implications of our results for understanding the OMZ dynamics off Peru are discussed.
Highlights
The upwelling region off Peru hosts a complex biogeochemical system that is unique for at least two reasons
Several deepenings of the thermocline take place that correspond most of the time to El Niño episodes and that are associated with enhanced salinity
The record encompasses one of the few strong equatorial Pacific (EP) El Niño events observed over the last 5 decades and the series of central Pacific (CP) El Niño events of the 2000s, which allows for the documentation of the oxygen minimum zone (OMZ) dynamics under two different El Niño–Southern Oscillation (ENSO) regimes and extends a previous study (Gutiérrez et al, 2008)
Summary
The upwelling region off Peru hosts a complex biogeochemical system that is unique for at least two reasons It is embedded into the permanent, intense and shallow oxygen minimum zone (OMZ) of the eastern tropical South Pacific (Gutiérrez et al, 2008). The OMZ is generated by the combination of high oxygen demand during organic matter remineralization and the sluggish ventilation in the region (Wyrtki, 1962; Helly and Levin, 2004). It is wide in vertical extension (∼ 500 m) and intense (< 22.5 μmol kg−1), and at some latitudes the upper. Recent modeling studies highlight the important role of submesoscale to mesoscale dynamics in constraining the upper OMZ meridional boundaries (Bettencourt et al, 2015; Vergara et al, 2016)
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