Tropical Marine Ecology. Daniel M. Alongi

Tropical Marine Ecology - Daniel M. Alongi


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activities.

      The El Niño event of 2015/2016 was initiated in boreal spring by a series of westerly wind events. This wind forcing triggered downwelling oceanic Kelvin waves, thus reducing the upwelling of cold subsurface waters in the eastern Pacific cold tongue, leading to surface warming in the central and eastern Pacific. The positive SST anomaly shifted atmospheric convection from the western Pacific Warm Pool to the central equatorial Pacific, causing a reduction in equatorial trade winds, which in turn intensified surface warming through positive feedback. Termination of the 2015/2016 event was associated with ocean dynamics and the slow discharge of equatorial heat into off‐equatorial regions. The event started to decline in early 2016 and transitioned into a weak La Niña in mid‐2016.

      The most dramatic example of the impact of an El Niño event on oceanographic processes is the Peruvian upwelling system (Chapter 10, Section 10.9.2). During El Niño, the thermocline and nutricline deepen significantly during the passage of coastal‐trapped waves within the Peruvian upwelling system. While the upwelling‐favourable wind increases, the coastal upwelling is compensated by a shoreward geostrophic near‐surface current. The depth of upwelling source waters remains unchanged during El Niño, but their nutrient content decreases dramatically, which along with a mixed layer depth increase, impacting phytoplankton growth. Offshore of the coastal zone, enhanced eddy‐induced subduction during El Niño plays a potentially important role in nutrient loss.

      Another dramatic example of the effect of an El Niño event are mass coral bleaching events (Section 13.2). A relatively modern phenomenon first reported in the 1980s, bleaching of corals has been unequivocally linked to SSTs above the upper thermal tolerance limits of corals and is widespread typically during El Niño events.

Schematic illustration of the three phases of the El Niño-Southern Oscillation (ENSO).

      Source: Public domain image from https://www.pmel.noaa.gov/elnino (accessed November 13, 2020). © United States Department of Commerce.

      The IOD results in two large‐scale patterns in countries bordering the Indian Ocean: (i) anomalously high land temperature and rainfall in the western Indian Ocean and low land temperature and rainfall in the east and (ii) enhanced rainfall over the Asian monsoonal trough, extending from Pakistan up to southern China. During IOD events, biological productivity of the eastern Indian Ocean increases as does the frequency of coral deaths. The IOD also affects rainfall over Australia and eastern Africa. The IOD is characterised by (i) a Walker cell anomaly over the equator in the Indian Ocean, (ii) deep modulation of the monsoonal westerlies, and (iii) a Hadley cell anomaly over the Bay of Bengal (Fan et al. 2017). The IOD is important to global climate as about 50% of IOD events over the past century have co‐occurred with ENSO events.

      Both ENSO and the IOD interact with a phenomenon called the Madden‐Julian Oscillation or MJO (Zhang 2005). The MJO is a major source of intra‐annual variability in the tropical atmosphere and often results in breaks and bursts of monsoonal activity, helping to invigorate tropical cyclones (e.g. Cyclone Winston in 2016). The MJO also modulates cyclone development in the Caribbean. Even though it originates in the equatorial Indian and western Pacific Oceans, the MJO affects equatorial surface winds in the tropical Atlantic. The MJO interacts with the underlying ocean to influence weather and climate, especially over the Pacific Islands, monsoonal Asia and Australia, South America, and Africa. The interannual variability


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