Abstract
Growing evidence indicates that the atmospheric and oceanic circulation experiences a systematic poleward shift in a warming climate. However, the complexity of the climate system, including the coupling between the ocean and the atmosphere, natural climate variability and land-sea distribution, tends to obfuscate the causal mechanism underlying the circulation shift. Here, using an idealised coupled aqua-planet model, we explore the mechanism of the shifting circulation, by isolating the contributing factors from the direct CO_2 forcing, the indirect ocean surface warming, and the wind-stress feedback from the ocean dynamics. We find that, in contrast to the direct CO_2 forcing, ocean surface warming, in particular an enhanced subtropical ocean warming, plays an important role in driving the circulation shift. This enhanced subtropical ocean warming emerges from the background Ekman convergence of surface anomalous heat in the absence of the ocean dynamical change. It expands the tropical warm water zone, causes a poleward shift of the mid-latitude temperature gradient, hence forces a corresponding shift in the atmospheric circulation and the associated wind pattern. The shift in wind, in turn drives a shift in the ocean circulation. Our simulations, despite being idealised, capture the main features of the observed climate changes, for example, the enhanced subtropical ocean warming, poleward shift of the patterns of near-surface wind, sea level pressure, storm tracks, precipitation and large-scale ocean circulation, implying that increase in greenhouse gas concentrations not only raises the temperature, but can also systematically shift the climate zones poleward.
Highlights
To understand how the ocean circulation responds to a shift in the atmospheric circulation, we show the results from the C0W1 experiment
We suggest that the ocean dynamics are important for capturing the full mechanisms, especially, the enhanced subtropical ocean warming generated by mean ocean circulation
Our study suggests that the enhanced subtropical warming is not due to atmosphere circulation changes, but has an oceanic origin, which relies on the background oceanic circulation
Summary
An increasing amount of evidence suggests that the atmospheric and oceanic circulation is shifting towards the poles under climate change (Thompson et al 2000; Marshall 2003; Fu et al 2006; Hu and Fu 2007; Lu et al 2007; Seidel et al 2008; Screen et al 2018). Following the finding of shifting large-scale ocean circulation, Yang et al (2020a, 2020b) highlight that the entire atmospheric and oceanic circulation is moving towards the higher latitudes, which is not solely owing to natural climate variability. This is because that many of the observed climate trends, such as the patterns of sea level pressure (SLP), sea surface height (SSH) and nearsurface winds, well resemble the patterns obtained from the climate simulations forced by increasing greenhouse gases. This idealised approach allows us to partition the full circulation response into different mechanisms in a quantitative manner, so as to pinpoint the leading cause for the circulation shifts in both ocean and atmosphere
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