Abrupt climate change is abundant in geological records, but climate models rarely have been able to simulate such events in response to realistic forcing. Here we report on a spontaneous abrupt cooling event, lasting for more than a century, with a temperature anomaly similar to that of the Little Ice Age. The event was simulated in the preindustrial control run of a highresolution climate model, without imposing external perturbations. Initial cooling started with a period of enhanced atmospheric blocking over the eastern subpolar gyre. In response, a southward progression of the sea-ice margin occurred, and the sea-level pressure anomaly was locked to the sea-ice margin through thermal forcing. The cold-core high steered more cold air to the area, reinforcing the sea-ice concentration anomaly east of Greenland. The sea-ice surplus was carried southward by ocean currents around the tip of Greenland. South of 70°N, sea ice already started melting and the associated freshwater anomaly was carried to the Labrador Sea, shutting off deep convection. There, surface waters were exposed longer to atmospheric cooling and sea surface temperature dropped, causing an even larger thermally forced high above the Labrador Sea. In consequence, east of Greenland, anomalous winds changed from north to south, terminating the event with similar abruptness to its onset. Our results imply that only climate models that possess sufficient resolution to correctly represent atmospheric blocking, in combination with a sensitive sea-ice model, are able to simulate this kind of abrupt climate change.climate modeling | thermohaline circulation | Great Salinity Anomaly A common definition of abrupt climate change is that the climate is undergoing a transition at a faster rate than changes in the external forcing. Dansgaard-Oeschger (DO) events are the iconic examples of such abrupt climate change, featuring the last glacial period as recorded in Greenland ice cores (1). DO events have been linked to large variations of the Atlantic meridional overturning circulation (AMOC), forced by freshwater input into the North Atlantic (2). This theory has been corroborated by results from coarse-resolution climate models with simplified atmospheric dynamics (3, 4). However, more sophisticated climate models show a temperature response that is still weak compared with DO events (5), even in the case of unrealistically large freshwater forcing. Recently, it has been argued that sea ice might play a key role in the onset of DO events (6, 7). A displacement of the ice edge rapidly changes the amount of absorbed shortwave radiation due to the ice-albedo feedback, but also it reduces heat release from the ocean to the atmosphere. Both processes cool the atmosphere and the ocean surface. Series of interactions between ocean and cryosphere may build and erode a freshwater halocline in the Nordic seas, promoting large changes in sea ice that can be associated with changes between cold stadials and warm interstadials (8). In this scenario, the AMOC continues to...
