Abstract
Abstract. The influence of reduced solar forcing (grand solar minimum or geoengineering scenarios like solar radiation management) on the Atlantic Meridional Overturning Circulation (AMOC) is assessed in an ensemble of atmosphere–ocean–chemistry–climate model simulations. Ensemble sensitivity simulations are performed with and without interactive chemistry. In both experiments the AMOC is intensified in the course of the solar radiation reduction, which is attributed to the thermal effect of the solar forcing: reduced sea surface temperatures and enhanced sea ice formation increase the density of the upper ocean in the North Atlantic and intensify the deepwater formation. Furthermore, a second, dynamical effect on the AMOC is identified driven by the stratospheric cooling in response to the reduced solar forcing. The cooling is strongest in the tropics and leads to a weakening of the northern polar vortex. By stratosphere–troposphere interactions, the stratospheric circulation anomalies induce a negative phase of the Arctic Oscillation in the troposphere which is found to weaken the AMOC through wind stress and heat flux anomalies in the North Atlantic. The dynamic mechanism is present in both ensemble experiments. In the experiment with interactive chemistry, however, it is strongly amplified by stratospheric ozone changes. In the coupled system, both effects counteract and weaken the response of the AMOC to the solar forcing reduction. Neglecting chemistry–climate interactions in model simulations may therefore lead to an overestimation of the AMOC response to solar forcing.
Highlights
The Atlantic Meridional Overturning Circulation (AMOC) is an important component of climate variability in the North Atlantic region (Kuhlbrodt et al, 2007; Stocker, 2013)
Sensitivity experiments for different solar minima and model configurations with and without chemistry–climate interactions have been carried out to study the response of the AMOC to reduced solar forcing and the modulating role of chemistry–climate interactions
Without interactive chemistry the response of the AMOC is dominated by the direct thermal effect, leading to an intensification of the overturning circulation
Summary
The Atlantic Meridional Overturning Circulation (AMOC) is an important component of climate variability in the North Atlantic region (Kuhlbrodt et al, 2007; Stocker, 2013). Understanding the variations in the strength of this circulation is important in particular for future climate change (Stocker and Schmittner, 1997; Manabe and Stouffer, 1999; Mikolajewicz and Voss, 2000; Gregory et al, 2005), decadal climate predictions (Griffies and Bryan, 1997; Meehl et al, 2009), and with respect to potential abrupt climatic changes as proposed for the past (Stocker and Wright, 1991; Stocker, 2000; Clark et al, 2002). Several processes are involved in driving the AMOC, ranging from internal processes of the climate system such as the thermohaline process (Wunsch, 2002; Kuhlbrodt et al, 2007; Lozier, 2010) to external forcing (Otterå et al, 2010).
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