The strength of the wind has an important influence on ocean circulation. This is particularly true for extreme events such as storm fronts, tropical storms and cyclones. These weather patterns, which last from a few days to a few weeks, will change in the future due to climate change. In particular, the average energy input into the ocean from mid-latitude storms is expected to decrease, while equatorial regions will become more active. Scientists call these different weather patterns “Atmospheric Synoptic Variability” (ASV).
Researchers Olaf Duteil from the GEOMAR Helmholtz Centre for Ocean Research Kiel and Wonsun Park from the IBS Center for Climate Physics and Pusan National University, Korea, have now for the first time investigated 1 the integrated effects of long-term changes in these weather patterns on the Pacific basin in a modelling study. The results show how important it is to take these changes into account in climate models.
From a climate point of view, the weather is usually considered as “noise” and is not systematically analysed in long-term climate projections, say the two researchers. However, it is not enough to look at average atmospheric properties, such as mean wind speeds, to understand the influence of climate change on the ocean, it is crucial to consider the cumulative effect of short-term changes in weather patterns to get a complete picture.
The researchers expect that future changes in ASV will affect the mixing of the ocean’s layers, as a smaller or larger input of kinetic energy into the ocean due to weather phenomena will lead to less or more mixing, respectively. The researchers predict that the reduction in ASV in subtropical regions will lead to a shallowing of the mixing layer in the ocean, while it will become deeper at the equator as ASV increases.
They also show that a future reduction in ASV decreases the strength of oceanic circulation systems – the so-called subtropical and tropical cells – and the large-scale ocean circulation. These systems connect mid-latitudes and equatorial latitudes via upper ocean pathways. They are driven by the trade winds north and south of the equator, regulate the upwelling of equatorial waters, and play a fundamental role in determining the surface temperature of the oceans and thus primary productivity in the tropics.
This study highlights the need to better quantify ASV and weather patterns in climate models, as changes in ASV have a large impact on future upper ocean circulation and mean properties.