Abstract
Prolonged high-temperature extreme events in the ocean, marine heatwaves, can have severe and long-lasting impacts on marine ecosystems, fisheries and associated services. This study applies a marine heatwave framework to analyse a global sea surface temperature product and identify the most extreme events, based on their intensity, duration and spatial extent. Many of these events have yet to be described in terms of their physical attributes, generation mechanisms, or ecological impacts. Our synthesis identifies commonalities between marine heatwave characteristics and seasonality, links to the El Niño-Southern Oscillation, triggering processes and impacts on ocean productivity. The most intense events preferentially occur in summer, when climatological oceanic mixed layers are shallow and winds are weak, but at a time preceding climatological maximum sea surface temperatures. Most subtropical extreme marine heatwaves were triggered by persistent atmospheric high-pressure systems and anomalously weak wind speeds, associated with increased insolation, and reduced ocean heat losses. Furthermore, the most extreme events tended to coincide with reduced chlorophyll-a concentration at low and mid-latitudes. Understanding the importance of the oceanic background state, local and remote drivers and the ocean productivity response from past events are critical steps toward improving predictions of future marine heatwaves and their impacts.
Highlights
Prolonged high-temperature extreme events in the ocean, marine heatwaves, can have severe and long-lasting impacts on marine ecosystems, fisheries and associated services
El Niño—Southern Oscillation (ENSO) events are often associated with extreme ocean temperatures that would qualify them as marine heatwaves (MHWs), this research is generally framed in terms of interannual variability
As event severity and category depends on both sea surface temperature (SST) and on local seasonally-varying SST variability, regions with the highest recorded category MHW and highest intensity MHW do not typically align
Summary
Prolonged high-temperature extreme events in the ocean, marine heatwaves, can have severe and long-lasting impacts on marine ecosystems, fisheries and associated services. This study applies a marine heatwave framework to analyse a global sea surface temperature product and identify the most extreme events, based on their intensity, duration and spatial extent Many of these events have yet to be described in terms of their physical attributes, generation mechanisms, or ecological impacts. Prolonged periods of anomalously warm ocean temperatures, marine heatwaves (MHWs), are a major threat to marine ecosystems and their functioning, that have resulted in devastating and long-lasting impacts marine on scales from hundreds to thousands of k ilometers[1,2,3,4,5,6,7] These extreme events are by definition rare, marine heatwaves with notable ecological impacts have been occurring more frequently in recent y ears[4,8,9,10]. ENSO events and deep atmospheric convection in the tropics more generally, can trigger remote, extra-tropical MHWs via the propagation of planetary scale oceanic or atmospheric w aves[3,17,20,26,27]
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